Tài liệu Báo cáo khoa học: Antioxidant defences in cybrids harboring mtDNA mutations associated with Leber’s hereditary optic neuropathy docx

In spite of reduced SOD activities in all LHON cybrids, and of low GPx and GR activities in cells with the most severe 3460⁄ ND1 and 11778 ⁄ ND4 mutations, GSH and GSSG content were not

mutations associated with Leber’s hereditary optic

neuropathy

Maura Floreani1, Eleonora Napoli1,2, Andrea Martinuzzi2, Giorgia Pantano2, Valentina De Riva2, Roberta Trevisan1,2, Elena Bisetto1,2, Lucia Valente1, Valerio Carelli3and Federica Dabbeni-Sala1

1 Department of Pharmacology and Anesthesiology, Pharmacology Section, University of Padova, Italy

2 ‘E Medea’ Scientific Institute, Conegliano Research Centre, Conegliano, Italy

3 Department of Neurological Sciences, University of Bologna, Italy

Leber’s hereditary optic neuropathy (LHON), the first

disease to be linked with a maternally inherited

mtDNA point mutation [1], is a genetic form of retinal

ganglion cell degeneration leading to loss of central

vision and optic nerve atrophy occurring

predomin-antly in young males [2] Three pathogenic mutations

at nucleotides 11778, 3460 and 14484, affecting,

respectively, ND4, ND1 and ND6 subunit genes of complex I of the respiratory chain, are most often associated with the disease, even though other rare pathogenic mutations have been reported [2] Com-plex I dysfunction is postulated to underlie LHON pathogenesis However, the details of complex I dys-function in LHON and its consequences on cellular

Keywords

antioxidant enzymes; galactose medium;

GSH and GSSG; Leber’s hereditary optic

neuropathy (LHON) cybrids; oxidative stress

Correspondence

A Martinuzzi, ‘E Medea’ Scientific Institute,

Conegliano Research Centre, via Costa Alta

37, 31015 Conegliano (TV), Italy

E-mail: Andrea.martinuzzi@cn.lnf.it

(Received 2 October 2004, revised 13

December 2004, accepted 22 December

2004)

doi:10.1111/j.1742-4658.2004.04542.x

Oxidative stress and imbalance between free radical generation and detoxi-fication may play a pivotal role in the pathogenesis of Leber’s hereditary optic neuropathy (LHON) Mitochondria, carrying the homoplasmic

11778⁄ ND4, 3460 ⁄ ND1 and 14484 ⁄ ND6 mtDNA point mutations associ-ated with LHON, were used to generate osteosarcoma-derived cybrids Enhanced mitochondrial production of reactive oxygen species has recently been demonstrated in these cybrids [Beretta S, Mattavelli L, Sala G, Trem-olizzo L, Schapira AHV, Martinuzzi A, Carelli V & Ferrarese C (2004) Brain 127, 2183–2192] The aim of this study was to characterize the anti-oxidant defences of these LHON-affected cells The activities of glutathione peroxidase (GPx), glutathione reductase (GR), superoxide dismutases (SOD) and catalase, and the amounts of glutathione (GSH) and oxidized glutathione (GSSG) were measured in cybrids cultured both in glucose-rich medium and galactose-rich medium The latter is known to cause oxidative stress and to trigger apoptotic death in these cells In spite of reduced SOD activities in all LHON cybrids, and of low GPx and GR activities in cells with the most severe 3460⁄ ND1 and 11778 ⁄ ND4 mutations, GSH and GSSG content were not significantly modified in LHON cybrids cultured

in glucose medium In contrast, in galactose, GSSG concentrations increased significantly in all cells, indicating severe oxidative stress, whereas

GR and MnSOD activities further decreased in all LHON cybrids These data suggest that, in cells carrying LHON mutations, there is a decrease in antioxidant defences, which is especially evident in cells with mutations associated with the most severe clinical phenotype This is magnified by stressful conditions such as exposure to galactose

Abbreviations

CuZnSOD, cupper zinc superoxide dismutase; DMEM, Dulbecco’s modified Eagle’s medium; GSH, glutathione; GSSG, oxidized glutathione; GPx, GSH peroxidase; GR, GSSG reductase; LHON, Leber’s hereditary optic neuropathy; MnSOD, manganese superoxide dismutase; ROS, reactive oxygen species; SOD, superoxide dismutase.

function, with particular reference to the specific

ret-inal ganglion cell degeneration, are still poorly

under-stood

The biochemical phenotype of complex I

dysfunc-tion in LHON has been investigated in various

patient-derived tissues (lymphocytes, platelets, muscle)

and cell lines (fibroblasts and lymphoblasts) (reviewed

in [3]) Spectrophotometrically assessed complex I

spe-cific activity was essentially slightly affected by the

11778⁄ ND4 mutation and not at all by the

14484⁄ ND6 mutation, but the 3460 ⁄ ND1 mutation

consistently lowered the enzyme activity [4–6]

A useful experimental approach for the study of the

cellular phenotype associated with the LHON

muta-tions is provided by the transmitochondrial cytoplasmic

hybrid (cybrid) cellular model [6–9] Cybrids are

obtained by fusing a rho
cell line (host) completely

devoid of mtDNA with cytoplasts produced by

enuclea-tion of cells (donor) derived from patients or controls

[10] In this way, the mtDNA of a donor cell can be

studied in the context of a ‘neutral’ nuclear background

The current knowledge suggests that the 3460⁄ ND1

and 11778⁄ ND4 mutations consistently decrease

com-plex I-driven respiration, whereas the 14484⁄ ND6

mutation induces a milder defect [6] On the other

hand, complex I-dependent ATP synthesis is severely

affected in cybrids with all three common LHON

mutations (reviewed in [11]) However, the limited

clin-ical expression of LHON suggests that the total ATP

cellular content is compensated in most tissues

Con-currently, there is a potential for stably increased

production of reactive oxygen species (ROS) [2,3,12]

Indeed an excess of ROS production, in particular

mitochondrial superoxide anion, has been observed in

neuronal (NT2) cybrid cells carrying the 11778⁄ ND4

and 3460⁄ ND1 LHON mutations, after retinoic

acid-induced differentiation [13] and, more recently, in

osteosarcoma-derived cybrid cell lines carrying the

three pathogenic mutations 11778⁄ ND4, 3460 ⁄ ND1

and 14484⁄ ND6 [14]

Under such conditions, oxidative stress may become

the prevalent pathological consequence of complex I

dysfunction and trigger apoptotic cell death [15] In

accordance with this view, two recent studies using

different models showed the convergent result that

LHON pathogenic mutations predispose cells to

apop-tosis [16,17]

As oxidative stress and imbalance between free

rad-ical generation and detoxification may play a pivotal

role in LHON pathogenesis, the aim of this study was

to investigate the level and efficiency of antioxidant

defences in cells carrying the most common LHON

mutations Therefore, mitochondria carrying the

homoplasmic 11778⁄ ND4, 3460 ⁄ ND1 and 14484 ⁄ ND6 mtDNA point mutations were used to generate osteo-sarcoma-derived cybrids In these cells, in which we observed different extents of reduced oxygen consump-tion, we measured the basal content of glutathione (GSH), oxidized glutathione (GSSG) and the activities

of the antioxidant enzymes glutathione peroxidase (GPx; EC 1.11.1.9), glutathione reductase (GR; EC 1.8.1.7), superoxide dismutase (SOD; EC 1.15.1.1) and catalase (EC 1.11.1.6) For comparison, we also carried out all determinations on cybrids repopulated with control mitochondria Furthermore, we measured the same parameters in the same cybrids subjected to glu-cose deprivation and galactose replacement in the cul-ture medium, an experimental condition shown to accelerate apoptotic death in cells bearing LHON mutations [17] As under these conditions the cells are forced to rely on mitochondrial respiratory chain for their ATP production, glucose replacement with galac-tose represents an ideal system for studying a response

to metabolic⁄ oxidative stress in cells showing impaired mitochondrial function

Results

Oxygen consumption in control and LHON cybrids

The results reported in Fig 1 allow a comparison of oxygen consumption between multiple controls and

Fig 1 Oxygen consumption in individual cybrid cell lines Assay conditions are described in Experimental procedures Values are expressed as fmol oxygen consumedÆmin)1per cell, and are means from two to seven different clones each assessed in at least three independent experiments Cell lines are grouped into controls and

11778 ⁄ ND4 (11778), 3460 ⁄ ND1 (3460) and 14484 ⁄ ND6 (14484) LHON cybrids The dotted line represents the mean of each group.

***P < 0.001.

LHON cybrids Grouping all control cybrids, and

grouping LHON cybrids by pathogenic mutation, it is

evident that mitochondrial respiration is significantly

decreased in LHON cybrids carrying the most severe

11778⁄ ND4 and 3460 ⁄ ND1 point mutation, the mean

reduction in respiration compared with the controls

being 29.3% (P < 0.001) and 33.5% (P < 0.001),

respectively In contrast, in 14484⁄ ND6 affected cybrids

the reduction was only 8.9% [P¼ nonsignificant (NS)],

confirming the milder phenotype of the 14484⁄ ND6

mutation As no detectable differences were observed

among the data obtained from different clones of the

same cell line, or among data obtained in single controls

and in single cell lines affected by the same mtDNA

mutation, we decided to carry out the following

experiments in a single clone representative of each

independent line (HPC7, control; HFF3, 11778⁄ ND4;

HMM12, 3460⁄ ND1; HL180, 14484 ⁄ ND6)

Antioxidant defences in cybrids incubated

in glucose medium

The pattern of antioxidant defences was evaluated in

cybrids maintained in basal culture conditions, i.e in

the presence of high glucose concentration (25 mm;

glu-) in the medium, which was Dulbecco’s modified

Eagle’s medium (DMEM) The data reported in

Table 1 clearly indicate that both GSH and GSSG

concentrations were similar in all cybrids tested GSH

concentration in cells bearing 3460⁄ ND1 and

11778⁄ ND4 mutations tended to be lower than in

other cybrids, but the observed differences were not

statistically significant As expected, in basal

condi-tions, all cells maintained a very high ratio between

reduced and oxidized glutathione, the percentage of

GSSG with respect to total glutathione (GSH +

GSSG) being about 0.4 to 0.5% in all cell lines

In Fig 2 the activities of the glutathione-related

enzymes, GPx and GR, are reported Total GPx

activ-ity measured in cells with a 3460⁄ ND1 mutation was

less than half of the activity present in controls In contrast, there were no significant differences from the controls in the enzymatic activities of cells with

14484⁄ ND6 or 11778 ⁄ ND4 mutations GR activity in cells carrying the 3460⁄ ND1 or the 11778 ⁄ ND4 muta-tion was significantly lower than in controls or cybrids carrying the 14484⁄ ND6 mutation Also in this case, the activity present in cells bearing the mild

14484⁄ ND6 mutation was not different from that in control cybrids

When we assessed the activity of catalase, we did not find any significant difference among the various cybrid lines (data not shown)

To complete the analysis of antioxidant enzyme profile in cybrids maintained in glu-DMEM, cytosolic CuZnSOD and mitochondrial MnSOD were meas-ured CuZnSOD and MnSOD protein in control and LHON-affected cybrids was quantified by Western blot using a specific antiserum (Fig 3) Densitometric

Table 1 GSH and GSSG content (nmol per mg protein) in control

and LHON-affected cybrid cells cultured in glu-DMEM The results

are means ± SD from four independent experiments carried out in

duplicate on two dishes for each experiment.

% GSSG ⁄ (GSH + GSSG) Controls 38.90 ± 4.10 0.16 ± 0.04 0.409

14484 ⁄ ND4 mutants 40.88 ± 6.01 0.15 ± 0.04 0.365

3460 ⁄ ND1 mutants 34.16 ± 4.16 0.13 ± 0.01 0.379

11778 ⁄ ND6 mutants 35.29 ± 6.16 0.18 ± 0.12 0.513

Fig 2 GPx and GR activities in control and LHON-affected cybrid cells cultured in glucose-supplemented culture medium (glu-DMEM) Culture and assay conditions are described in Experimen-tal procedures The results are means ± SD from four independent experiments carried out in duplicate using two dishes for each experiment **P < 0.01; ***P < 0.001.

analysis of the blots (Fig 4A) shows a trend of

increase in CuZnSOD and MnSOD in

LHON-affec-ted cybrids with respect to controls, the difference

being significant (P < 0.01) for CuZnSOD in cells

carrying the 11778⁄ ND4 mutation However, the high

expression of SOD proteins in cybrids with

LHON-associated mutations did not correspond to higher

enzymatic activities The results reported in Fig 4B

in fact indicate that CuZnSOD activity (clear

col-umns) tended to be lower in all cybrid lines

com-pared with controls, whereas MnSOD activity (dotted

columns) was significantly (P < 0.05) lower in cells

bearing the 14484⁄ ND6 mutation When CuZnSOD

and MnSOD activities were normalized to the

respective protein amounts, assessed as densitometric

units, the activities of the enzymes were always lower

(P < 0.05) in mutated cybrids than controls

(Fig 4C)

Antioxidant defences in cybrids incubated

in galactose medium

GSSG concentrations were measured during a 24-h

time course experiment in cells cultured in gal-DMEM

(Fig 5) and, for comparison, in glu-DMEM In the

latter condition, GSSG did not change over time (data

not shown) In contrast, a marked time-dependent

increase in GSSG concentration was observed in

cy-brids cultured in galactose Controls and 14484⁄ ND6

mutated cells showed similar behavior over time; after

10 to 16 h of incubation in gal-DMEM, GSSG

con-centrations had increased significantly (P < 0.001)

Fig 3 Western blotting analysis of content of CuZnSOD (16 kDa)

and MnSOD (25 kDa) proteins in control and LHON-affected cybrid

cells maintained in glucose-supplemented culture medium

(glu-DMEM) Tubulin (55 kDa) was used as a reference protein The

blots depicted are representative of three separate experiments.

Fig 4 CuZnSOD and MnSOD activities in control and LHON-affec-ted cybrid cells cultured in glucose-supplemenLHON-affec-ted culture medium (glu-DMEM) (A) Densitometric quantification of CuZnSOD (unfilled columns) and MnSOD (filled columns) in control and LHON-affected cybrid cells Results are means ± SD from three separate blots and are expressed as arbitrary densitometric units normalized to tubulin (B) CuZnSOD (filled columns) and MnSOD (unfilled columns) activit-ies were assayed as described by Oberley & Spitz [47], as des-cribed in Experimental procedures The activities are expressed in UÆmg protein)1 The results are means ± SD from six independent experiments carried out in duplicate using two dishes for each experiment (C) The activities of CuZnSOD (unfilled columns) and MnSOD (filled columns) obtained in the cell lysates (40 lg protein) were normalized to densitometric units calculated from the respect-ive Western blot analysis carried out on the same amount of pro-tein from the same cell lysate The results are means ± SD from three independent experiments *P < 0.05; **P < 0.01.

compared with the respective values observed in

glu-DMEM (data not shown) In contrast, in 3460⁄ ND1

mutated cells, GSSG had increased significantly

(P < 0.05) after 6 h of treatment, and after 24 h the

GSSG concentration was about 30-fold higher than

that measured in glucose medium Moreover, starting

at 6 h of incubation in galactose, these cells had

signi-ficantly (P < 0.001) higher GSSG concentrations than

those measured at the same times in controls and

14484⁄ ND6 mutated cybrids The increase in GSSG

concentration was even more marked in 11778⁄ ND4

affected cells; with respect to the concentrations found

in glucose-treated cells, the increase in GSSG began to

be significant (P < 0.01) after 2 h of treatment and peaked after 16 h, reaching a 45-fold increase Between

2 and 16 h of the galactose challenge, GSSG concen-trations in these cybrids were significantly (P < 0.001) higher than those measured at the same times in all other cybrids Compared with other mutant cybrids, the GSSG concentration in cells with the 11778⁄ ND4 mutation tended to decrease after 16 h of treatment, possibly indicating a severe cellular defect

Cellular GSH did not decrease as a consequence of glucose deprivation, but rather increased in some cybrid lines (Fig 5) In both controls and cells with the

14484⁄ ND6 mutation, GSH concentrations measured after treatment with gal-DMEM were not significantly different from those obtained in glu-DMEM (data not shown), and no significant differences were observed at any time in GSH concentrations between controls and

14484⁄ ND6 affected cybrids in gal-DMEM In contrast, GSH markedly increased in cells carrying the

3460⁄ ND1 and 11778 ⁄ ND4 mutations, which once again showed similar behavior A 12-h incubation in galactose caused a significant (P < 0.01 to 0.001) increase in GSH concentration compared with the values observed in glu-DMEM (data not shown) The GSH concentration in both cell lines had doubled after 16 to 24 h in gal-DMEM and was significantly (P < 0.01 to 0.001) higher than in controls and 14484⁄ ND6 affected cells starting at 10 h of the galactose challenge However, in spite of this marked increase in GSH concentration, the percentage of GSSG with respect to total glutathione (GSSG + GSH)

in cybrids carrying the 3460⁄ ND1 and 11778 ⁄ ND4 mutations was significantly higher than that measured

in controls and cells with the 14484⁄ ND6 mutation (Table 2), indicating a large imbalance in glutathione homeostasis and conditions of extreme oxidative stress

in these cells

Fig 5 Time course of GSSG and GSH content in controls and

cybrids carrying the three primary LHON mutations incubated in

glucose-free ⁄ galactose-supplemented DMEM Culture and assay

conditions are described in Experimental procedures The results

are means ± SD from four independent experiments carried out in

duplicate using two dishes for each experiment *P < 0.05;

**P < 0.01, ***P < 0.001.

Table 2 Percentage of GSSG vs (GSH + GSSG) in control and LHON-affected cybrid cells cultured in gal-DMEM for 6, 12 or 24 h The results, obtained from GSSG and GSH values reported in Fig 5 are means ± SD from four independent experiments carried out in duplicate on two dishes for each experiment.

Cell line

% GSSG ⁄ (GSH + GSSG)

Controls 0.79 ± 0.04 1.96 ± 0.02 4.05 ± 0.02

14484 ⁄ ND4 mutants 0.63 ± 0.04 1.71 ± 0.02 4.15 ± 0.04

3460 ⁄ ND1 mutants 1.11 ± 0.01 a 2.17 ± 0.02 a 5.33 ± 0.05 a

11778 ⁄ ND6 mutants 6.08 ± 0.06a 9.68 ± 0.10a 5.82 ± 0.05a

a

Significant difference from respective control value: P < 0.05.

When we measured the activities of the antioxidant

enzymes in cybrids maintained for 24 h in galactose

medium, we found that GPx and catalase activities

were not different from those in basal conditions (data

not shown) In contrast, in some cybrid lines, GR and

SOD activities were significantly affected by glucose

deprivation The results reported in Fig 6 indicate that

the cells carrying the 3460⁄ ND1 or 11778 ⁄ ND4

muta-tion had significantly lower GR activity than controls

and cybrids with the 14484⁄ ND6 mutation

Compar-ison of these results with those reported in Fig 2

shows that glucose deprivation caused a further

marked decrease in the already low GR activity

pre-sent in the 11778⁄ ND4 mutated cells, whereas the

trend of GR activity in the other cell lines was similar

to that observed when the cells were incubated in

nor-mal glucose medium

Incubation in galactose caused a dramatic decrease

in SOD activity, particularly mitochondrial MnSOD,

in all LHON cybrids (Fig 7) This decrease ranged

from 37% in the cells with the 14484⁄ ND6 mutation

to 68% in those with the 11778⁄ ND4 mutation,

com-pared with the controls Comparison of the results

reported in Fig 7 with the data in Fig 4B clearly

indi-cates that MnSOD activity in control cells was not

affected by the incubation in gal-DMEM

CuZn-SOD activity was less affected by glucose

deprivation In gal-DMEM, only the 3460⁄ ND1

mutated cells had CuZn-SOD activity significantly

dif-ferent from that in controls, whereas in all other lines

it was similar to that observed in glu-DMEM (for

comparison, see Fig 4B)

Discussion

A complex I-driven chronic increase in oxidative stress has been suggested to be a relevant contributory factor

to retinal ganglion cell death and optic atrophy in LHON [2,3,12] The present results indicate that osteo-sarcoma-derived cybrids carrying the three most com-mon LHON pathogenic mutations in complex I subunit genes show a partial respiratory defect, assessed as a decrease in oxygen consumption, closely related to the severity of the clinical spectrum of the disease [2,3] In fact, a 29 to 34% decrease in cell respiration is observed

in cells bearing the 11778⁄ ND4 and 3460 ⁄ ND1 muta-tions, whereas a lower (
9%) decrease in oxygen con-sumption is present in cybrids with the 14484⁄ ND6 point mutation, compatible with the milder clinical phe-notype [6] In the same cybrids, a significant increase in ROS production has recently been reported [14]; in par-ticular, the highest ROS production was measured in cybrids bearing the 3460⁄ ND1 mutation, followed by

11778⁄ ND4 and 14484 ⁄ ND6 mutations In this study,

we also show, for the first time, that in these LHON-affected cells there is low efficiency of the antioxidant machinery, the 11778⁄ ND4 and 3460 ⁄ ND1 mutations expressing clearly the most severe phenotype The great-est vulnerability of these cells to metabolic⁄ oxidative stress is magnified by glucose deprivation and galactose replacement

Antioxidant defences in cybrids cultured

in glu-DMEM

We first assessed the antioxidant defences of LHON cybrids in glucose-supplemented medium (glu-DMEM),

Fig 6 GR activity in control and LHON-affected cybrid cells

cul-tured for 24 h in glucose-free⁄ galactose-supplemented culture

medium (gal-DMEM) Culture and assay conditions are described in

Experimental procedures The results are means ± SD from four

independent experiments carried out in duplicate using two dishes

for each experiment *P < 0.05; ***P < 0.001 a P < 0.05,

Signifi-cant differences from values of cybrid cells bearing the 3460 or

11778 mutation.

Fig 7 CuZnSOD (unfilled columns) and MnSOD activities (filled columns) in control and LHON-affected cybrid cells cultured for

24 h in glucose-free ⁄ galactose-supplemented culture medium (gal-DMEM).The activities are expressed in UÆmg protein)1, as des-cribed by Oberley & Spitz [47] The results are means ± SD from four independent experiments carried out in duplicate using two dishes for each experiment **P < 0.01; ***P < 0.001.

a condition in which cells derive their energy mainly

from anaerobic glycolysis [18] and ATP production is

ensured even in the presence of mitochondrial

dysfunc-tion [19,20] Under these culture condidysfunc-tions, LHON

cybrids grew normally, as previously reported [7,17]

However, some alterations in their antioxidant

machin-ery emerged, more clearly in cybrids carrying the

3460⁄ ND1 and 11778 ⁄ ND4 mutations in which GPx

and GR activities were significantly reduced As GPx

and GR are proteins encoded by the nuclear genome of

the parental 143B.TK– cells, which is constant among

the cybrid cell lines compared in this study, the low

GPx and GR activities in 3460⁄ ND1 and 11778 ⁄ ND4

mutated cybrids may be ascribed to post-translational

events It is well known that GR [21,22] and GPx [23]

activities are significantly decreased in the presence of

ROS or in a condition of drug-induced ROS

genera-tion As increased generation of ROS has been

observed in the glu-DMEM cultured cybrids,

partic-ularly 3460⁄ ND1 and 11778 ⁄ ND4 mutated cells [14],

we can hypothesize that the decrease in GPx and GR

activities displayed by these mutants may reflect the

higher ROS concentrations On the other hand,

signifi-cant increases in ROS production have also been

observed in NT2 neuronal-like cybrids carrying the

11778⁄ ND4 and 3460 ⁄ ND1 mutations [13] and in

human–ape xenomitochondrial cybrids partially

defici-ent in complex I [15] A ‘chronic’ oxidative insult may

also explain the apparent contradiction of SOD results

in LHON cybrids As shown by Western blot analysis,

the expression of CuZnSOD and MnSOD proteins

seems to be slightly increased in LHON cybrids

compared with controls, whereas the enzyme activities

are lower Both MnSOD and CuZnSOD proteins are

possibly upregulated as a compensatory mechanism,

but may be partially inactivated by oxidative damage

Complex I impairment in a variety of human diseases

has been previously reported in association with

MnSOD induction, although not all patients defective

in complex I displayed an increase in MnSOD activity

[24] Furthermore, not all tissues have the same ability

to upregulate MnSOD, as suggested by the different

behavior of skeletal and cardiac muscle observed in the

ANT1-knockout animal model of oxidative stress [25]

Moreover, MnSOD and CuZnSOD expression

increa-ses several fold in Saccharomyces cerevisiae during

menadione-induced oxidative stress, without a parallel

increase in their activities [26] CuZnSOD inactivation

has been ascribed to hydrogen peroxides [27], whereas

inactivation of MnSOD relates to peroxynitrite species,

generated by the interaction of superoxide anion

with nitric oxide [28], which can nitrate critical

tyrosine residues causing loss of enzyme activity [29]

Experiments are currently in progress in our laboratory

to evaluate protein nitrosylation in control and mutated cybrids cultured in glu-DMEM

Overall, our results indicate that, in spite of low effi-ciency in some antioxidant enzymes, particularly evi-dent in cells affected by the most severe LHON pathogenic mutations, the cybrids maintained in glu-cose-supplemented medium successfully manage the increased generation of ROS This is indicated by GSH and GSSG concentrations, which are not signifi-cantly modified in comparison with those of controls, and by the normal cell growth [17]

Antioxidant defences in cybrids cultured

in gal-DMEM When the cells were cultured in glucose-free⁄ galactose-supplemented medium, the situation dramatically changed The replacement of glucose by galactose in the culture medium (gal-DMEM) forces the cells to rely on oxidative phosphorylation for ATP production, which in the case of LHON cybrids is severely impaired when driven by complex I substrates [30] Galactose medium induces a dramatic time-dependent depletion of cellular ATP content [31] and a wave of apoptotic cell death [17] As peroxide scavenging via pyruvate as well as via NADPH-dependent reactions is decreased in these conditions, because the restricted flow of galactose to glucose 6-phosphate decreases NADPH availability [20,32], incubation in galactose is expected to induce a metabolic⁄ oxidative stress crisis, which aggravates the pathogenicity of LHON muta-tions In fact, LHON cybrids incubated in gal-DMEM show dramatic modifications in their antioxidant defences All LHON cybrids had GR activities that were significantly lower than in control cybrids, with a particularly large decrease in the 11778⁄ ND1 mutated cells Large modifications in glutathione homeostasis were also evident in cybrids carrying 11778⁄ ND4 or

3460⁄ ND1, as reflected by their earlier and more marked increases in GSSG concentration compared with the control and 14484⁄ ND6 mutated cybrids This accumulation of GSSG is the likely result of increased ROS production, when this exceeds the metabolic capabilities of GPx and GR A burst of oxi-dative stress resulting in enhanced formation of per-oxynitrite [29] in LHON cybrids may also explain the significant decrease in MnSOD activity observed after

a 24-h incubation in gal-DMEM

In cybrids bearing the most severe 3460⁄ ND1 and

11778⁄ ND4 mutations, we found a time-dependent, large increase in GSH This is not surprising, as very similar cellular behavior, i.e concurrent increase in

GSSG and GSH, has been observed in

multidrug-resist-ant human breast carcinoma cells treated with a

glu-cose-free medium [33] This indicates that the cells in

galactose medium increase glutathione synthesis, in an

attempt to counteract the increased production of

intra-cellular pro-oxidants As GR activity is greatly impaired

in 3460⁄ ND1 and 11778 ⁄ ND4 mutated cybrids, and

NADPH availability is decreased in gal-DMEM, the

GSH increase observed in these cells may be due to

de novoGSH synthesis, a two-step process catalyzed by

c-glutamylcysteine synthetase and GSH synthetase [34]

We did not directly measure c-glutamylcysteine

syn-thetase expression and⁄ or activity in cybrids in our

experimental conditions However, our hypothesis is

supported by a study reporting that rat lung epithelial

L2 cells respond to menadione-induced oxidative stress,

with a 2.5-fold increase in their GSH content obtained

through increased c-glutamylcysteine synthetase activity

[35] and increased transcription of the regulatory

sub-unit of c-glutamylcysteine synthetase itself [36] In spite

of the increase in GSH, however, the cybrids harboring

the most severe 3460⁄ ND1 and 11778 ⁄ ND4 mtDNA

mutations failed to maintain the percentage of GSSG

vs (GSH + GSSG) at values similar to those of the

controls or the cybrids with the 14484⁄ ND6 mutation,

indicating a situation of greater cellular distress This

imbalance in glutathione homeostasis may be closely

connected with the apoptotic death of LHON cybrids

grown in galactose medium [17] It is well known that

the redox state of thiols regulates the mitochondrial

permeability transition pore [37], its opening being

responsible for energy uncoupling, diminished

intracel-lular ATP concentrations, and release of cytochrome

cand other pro-apoptotic factors

Conclusions

Our study shows that cybrids carrying the three most

common mtDNA point mutations associated with

LHON show evidence of low efficiency of some of the

antioxidant enzymes, probably because of

post-transla-tional events The extent of this phenomenon seems to

be related to the severity of the biochemical defect

associated with the LHON mutation and possibly to

the amount of ROS generated by mitochondria,

corre-lating also with the clinical phenotype of the disease

Thus, the 14484⁄ ND6 mutation, which is associated

with a benign visual prognosis and normal complex I

activity [5] and no significant decrease in oxygen

con-sumption (present data), has the lowest ROS

produc-tion [14] and the mildest impairment in antioxidant

activity (present results) In contrast, the 3460⁄ ND1

and the 11778⁄ ND4 mutations, which consistently

decrease complex I activity [3,6] and oxygen consump-tion (present data) and are associated with severe neuropathology [38], are associated with the highest mitochondrial ROS production [14] and the least effi-cient antioxidant defences (present results) However, while in glucose medium, all LHON-affected cybrids retain the ability to buffer their dysfunctions, as shown

by the lack of modification in glutathione homeostasis and by their normal growth However, the modifica-tions described in the antioxidant machinery result in greater vulnerability of the cells to metabolic⁄ oxidative stress, as seen in galactose medium Under these condi-tions, a further decrease in some antioxidant activities (MnSOD and GR) and drastic impairment of glutathi-one homeostasis occur, particularly in cybrids with

3460⁄ ND1 and 11778 ⁄ ND4 mutations Taken together these results provide further insight into the patho-physiological consequences of LHON mutations, indi-cating that the unstable balance in which LHON cells live may be upset by any exogenous or endogenous condition (e.g exposure to drugs and⁄ or toxins, or changing hormonal status) that favors ROS genera-tion This may precipitate the cells into a metabolic crisis which in vivo may lead to apoptotic death of ret-inal ganglion cells and clinically expressed LHON

Experimental procedures

Materials

Tissue culture reagents were purchased from Gibco-Invitro-gen (Milan, Italy) Cumene hydroperoxide, NADPH, GSH, GSSG, xanthine, xanthine oxidase (from buttermilk), gluta-thione reductase (from baker’s yeast), nitroblue tetrazolium, 2-vinylpyridine and albumin were obtained from Sigma Chemical Co (St Louis, MO, USA) NaCl⁄ Pifrom Oxoid had the following composition: NaCl 8 gÆL)1, KCl 0.2 gÆL)1, Na2HPO4 1.15 gÆL)1 and KH2PO4 0.2 gÆL)1 (pH 7.3) All other reagents were of analytical grade and were used as received

Construction and characterization of cybrid cell lines

Cybrid cell lines were constructed from fibroblasts obtained, after informed consent, from skin biopsies of six members

of five unrelated families with clinically and molecularly defined LHON, previously reported [4,5], and from five unrelated controls Cells, grown in DMEM supplemented with 10% fetal calf serum, were then enucleated and fused with osteosarcoma-derived mtDNA-less cells (rho
206 derived from 143B.TK–, a gift from G Attardi) as described [10] After selection in uridine-deprived

bromodeoxyuridine-supplemented medium, several cybrid clones (a minimum of

two for each individual) repopulated with mtDNA from

each fibroblast cell line were isolated and expanded

More-over, to avoid possible confounding effects due to different

functional profiles of different batches of 143B.Tk–, and to

indirectly check the unstable nuclear genome of the 143B

cells, we measured the respiratory capacity of 143B cells

fro-zen just after being brought from the donor laboratory

(1993) or after various periods of time in culture (frozen in

1996, 1999, 2002) The observed values were all within the

range of experimental variation (± 10%)

The cybrids have been regularly checked for the presence

of the LHON pathogenic mutations 3460⁄ ND1, 11778 ⁄ ND4

and 14484⁄ ND6 following the standard PCR ⁄ restriction

fragment length polymorphism method [16,17] All LHON

cybrids used carried stably homoplasmic mtDNA mutations,

reconfirmed every 3 to 5 months

Moreover, a functional check of the cybrids was carried

out by determination of oxygen consumption, as described

previously [39] Briefly, the rate of oxygen consumption was

measured in intact cells with a Gilson 5⁄ 6 oxygraph on

samples of (4–5)· 106cells in 1.85 mL DMEM lacking

glu-cose supplemented with 5% dialyzed fetal calf serum at

37
C By this method, we tested five control lines, three

lines with the 11778⁄ ND4 mutation, two lines with

3460⁄ ND1 and two with 14484 ⁄ ND6 mutations Each line

is the result of a cybridization from a different individual,

and each bar shown in the graph of Fig 1 is the result of

averaging data obtained from two to seven different clones

each assessed in at least three independent experiments

A representative clone of each independent line (HPC7:

control; HFF3: 11778⁄ ND4; HMM12: 3460 ⁄ ND1; HL180:

14484⁄ ND6) was used for the extensive study detailed in

the following sections

Culture conditions

Cybrid cell lines were grown in DMEM supplemented with

10% fetal calf serum, 2 mm l-glutamine, 100 UÆmL)1

penicil-lin, 100 lgÆmL)1 streptomycin and 0.1 mgÆmL)1

bromode-oxyuridine For the experiments, the cells (
1.8 · 106) were

plated on 10-cm Petri dishes in 8 mL of the above reported

DMEM and maintained at 37
C in an incubator under a

humidified 5% CO2 atmosphere After 24 h, the culture

medium was replaced with fresh complete DMEM

supple-mented with 25 mm glucose (glu-DMEM) or with

glucose-free DMEM supplemented with 5 mm galactose, 5 mm

sodium pyruvate and 5% fetal calf serum (gal-DMEM), as

described by Ghelli et al [17] The cells were incubated at

37
C for 24 more hours

Measurement of GSH and GSSG

Cellular GSH and GSSG concentrations were measured

enzymatically [40], as described previously [41] Briefly, the

assay is based on the determination of a chromophoric product, 2-nitro-5-thiobenzoic acid, resulting from the reac-tion of 5,5¢-dithiobis-(2-nitrobenzoic acid) with GSH In this reaction, GSH is oxidized to GSSG, which is then reconverted into GSH in the presence of glutathione reduc-tase and NADPH The rate of 2-nitro-5-thiobenzoic acid formation is measured spectrophotometrically at 412 nm The cells [
(5–6) · 106

for each determination] were washed once with NaCl⁄ Piand then treated with 6% meta-phosphoric acid (1 mL per dish) at room temperature After 10 min, the acid extract was collected, centrifuged for

5 min at 18000 g at 4
C, and processed The cellular debris remaining on the plate was solubilized with 0.5 m KOH and assayed for protein content as described by Lowry

et al [42] For total glutathione determination, the above acid extract was diluted (1 : 6) in 6% metaphosphoric acid; thereafter to 0.1 mL supernatant were added 0.75 mL 0.1 m potassium phosphate⁄ 5 mm EDTA buffer (pH 7.4), 0.05 mL 10 mm 5,5¢-dithiobis-(2-nitrobenzoic acid) (pre-pared in 0.1 m phosphate buffer) and 0.08 mL 5 mm NADPH After a 3-min equilibration period at 25
C, the reaction was started by the addition of 2 U glutathione reductase (type III; Sigma; from bakers yeast; diluted in 0.1 m phosphate⁄ EDTA buffer) Product formation was recorded continuously at 412 nm (for 3 min at 25
C) with

a Shimadzu UV-160 spectrophotometer The total amount

of GSH in the samples was determined from a standard curve obtained by plotting known amounts (0.05 to 0.4 lgÆmL)1) of GSH against the rate of change in A412 GSH standards were prepared daily in 6% metaphosphoric acid and diluted in phosphate⁄ EDTA buffer (pH 7.4) For GSSG measurement, soon after preparation, the supernatant of acid extract was treated for derivatization with 2-vinylpyridine at room temperature for 60 min In a typical experiment, 0.15 mL supernatant was treated with

3 lL undiluted 2-vinylpyridine Then 9 lL triethanolamine was added The mixture was vigorously mixed, and the pH was checked; it was generally between 6 and 7 After

60 min, 0.1 mL aliquots of the samples were assayed by the procedure described above for total GSH measurement The amount of GSSG was quantified from a standard curve obtained by plotting known amounts of GSSG (0.05

to 0.20 lgÆmL)1) against the rate of change in absorbance GSH present in the samples was calculated as the differ-ence between total glutathione and GSSG concentrations

Assay of antioxidant enzyme activities

For measurement of GPx, GR and catalase activities, monolayer cells [
(2–3) · 106

] were washed three times with NaCl⁄ Pi before treatment directly on the dish with a solution consisting of 0.25 m sucrose, 10 mm Tris⁄ HCl (pH 7.5), 1 mm EDTA, 0.5 mm phenylmethanesulfonyl fluoride, 0.5 mm 1,4-dithio-dl-threitol and 0.1% (v⁄ v) Non-idet (solution A), to obtain complete lysis of intracellular

organelles Cells were then scraped from the plate, and the

samples were centrifuged for 30 min at 105 000 g Protein

measurements [42] and enzyme assays were carried out on

the clear supernatant fractions

Total GPx activity was measured by the coupled enzyme

procedure with glutathione reductase, as described by

Proh-aska & Ganther [43], using cumene hydroperoxide as

sub-strate Enzyme activity was monitored by following the

disappearance of NADPH at 340 nm for 3 min at 25
C

The incubation medium (final volume 1 mL) had the

follow-ing composition: 50 mm KH2PO4 (pH 7.0), 3 mm EDTA,

1 mm KCN, 1 mm GSH, 0.1 mm NADPH, 2 U glutathione

reductase and
300 lg protein After a 3-min equilibration

period at 25
C, the reaction was started by the addition of

0.1 mm cumene hydroperoxide dissolved in ethanol The

specific activity was calculated by using a molar absorption

coefficient obtained from a standard curve of NADPH (0.02

to 0.1 lmolÆmL)1), and GPx activity was expressed in nmol

NADPH consumed per mg proteinÆmin)1

GR activity was measured by the method of Carlberg &

Mannervik [44], by following the rate of oxidation of

NADPH by GSSG at 340 nm for 3 min at 25
C The

reac-tion mixture (final volume 1 mL) contained: 0.1 m KH2PO4

(pH 7.6), 0.5 mm EDTA, 1 mm GSSG, 0.1 mm NADPH,

and
300 lg protein The specific activity was calculated

by using a molar absorption coefficient obtained from a

standard curve of NADPH (0.02 to 0.1 lmolÆmL)1), and

GR activity was expressed in nmol NADPH consumed per

mg proteinÆmin)1

Total catalase activity was assayed by the method of

Aebi [45] Activity was measured by monitoring, for 30 s at

25
C, the decomposition of 10 mm H2O2 at 240 nm in a

medium (final volume 1 mL) consisting of 50 mm

phos-phate buffer (pH 7.0) and
100 lg protein Catalase

activ-ity was expressed as U per mg protein, assuming that 1 U

catalase decomposes 1 lmol H2O2Æmin)1

For MnSOD and CuZnSOD assays, after treatment of

2· 106 cells with solution A, an aliquot (0.6 mL) of cell

lysate was sonicated, on ice (2· 30 s bursts) with a Labsonic

U2000 sonicator (B Braun Biotech International,

Melsun-gen, Germany) and then centrifuged for 30 min at 105 000 g

as described by Siemankowski et al [46] The supernatant

was collected and dialyzed overnight in cold double-distilled

water to remove small interfering substances Enzyme assays

were carried out by the method of Oberley & Spitz [47], with

minor modifications Briefly, in 1 mL medium consisting of

50 mm KH2PO4(pH 7.8) and 0.1 mm EDTA, a

superoxide-generating system (0.15 mm xanthine plus 0.02 U xanthine

oxidase) was used together with 50 lm nitroblue tetrazolium

to monitor superoxide formation by following the changes in

colorimetric absorbance at 560 nm for 5 min at 25
C The

catalytic activities of the samples were evaluated as their

abil-ity to inhibit the rate of nitroblue tetrazolium reduction;

increasing amounts of protein (5 to 150 lg) were added

to each sample until maximum inhibition was obtained

SOD activity was expressed as U per mg protein, 1 U SOD activity being defined as the amount of protein causing half-maximal inhibition of the rate of nitroblue tetrazolium reduction To assess MnSOD activity, cell fractions were preincubated for 60 min at 0
C in the presence of 5 mm KCN, which produces total inhibition of Cu⁄ ZnSOD The latter activity was calculated as the difference between activit-ies in the absence and presence of KCN

Western blot assay of CuZnSOD and MnSOD

On the same cybrid cell lysates, obtained as reported above and used for SOD activity assays, Western blotting was car-ried as described by Dieterich et al [48] Equal amounts of protein (40 lg per lane) denatured in electrophoresis buffer containing 100 mm Tris⁄ HCl (pH 6.8), 8 mm dithiothreitol, 2% SDS, 2% glycerol, and 0.05% bromophenol blue at

95
C were electrophoresed on SDS ⁄ polyacrylamide gel (10% gel) and electrotransferred to a poly(vinylidene difluo-ride) membrane (Bio-Rad) The membrane was blocked with 5% nonfat dry milk in 0.02 m Tris⁄ HCl buffer, pH 7.5, containing 0.137 m NaCl and 0.1% (v⁄ v) Tween 20 (TBST) for 1 h at room temperature and then incubated with sheep anti-(human CuZnSOD) IgG (Calbiochem, Darmstadt, Ger-many) diluted 1 : 1000, anti-(human MnSOD) IgG diluted

1 : 10 000 (gift from John Guy, University of Florida), or anti-(human tubulin) IgG (Sigma) diluted 1 : 1000 After being washed with NaCl⁄ Pi⁄ 0.1%Tween, the blots were incubated with horseradish peroxidase-conjugated anti-sheep IgG (Calbiochem) diluted 1 : 10 000 at room tem-perature for 1 h After a final wash of the membrane with TBST, the immunoreactivity was detected with enhanced chemiluminescence detection solution (Sigma) The immuno-reactivity was detected in the same way as described above Quantitative analysis of the blots was carried out using the image jsoftware (http//rsb.info.nih.gov⁄ ij ⁄ )

Statistical analysis

Results are expressed as arithmetic means ± SD Compari-sons were made by one-way analysis of variance A P value

of less than 0.05 was considered significant

Acknowledgements

This work was supported, in part, by grants from MIUR (Italy) The financial support of Telethon Italy (project No GGP02323 to VC and AM) is gratefully acknowledged

References

1 Wallace DC, Singh G, Lott MT, Hodge JA, Schurr TG, Lezza AM, Elsas LJD & Nikoskelainen EK (1988)