Calcium Homeostasis and Reactive Oxygen Species Production in Cells Transformed by Mitochondria from Individuals with Sporadic Alzheimer's Disease

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Volume 17, Number 12, Issue of June 15, 1997 pp. 4612-4622
Copyright ©1997 Society for Neuroscience

Calcium Homeostasis and Reactive Oxygen Species Production in Cells Transformed by Mitochondria from Individuals with Sporadic Alzheimer's Disease

Jason P. Sheehan¹, Russel H. Swerdlow⁴, Scott W. Miller⁵, Robert E. Davis⁵, Jan K. Parks⁴, W. Davis Parker⁴, and Jeremy B. Tuttle²^,³
Departments of ¹ Neurological Surgery, ² Neuroscience, ³ Urology, and ⁴ Neurology, University of Virginia, Charlottesville, Virginia 22908, and ⁵ MitoKor Corporation, San Diego, California 92121

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Alzheimer's disease (AD) is associated with defects in mitochondrial function. Mitochondrial-based disturbances in calciumhomeostasis, reactive oxygen species (ROS) generation, and amyloidmetabolism have been implicated in the pathophysiology of sporadicAD. The cellular consequences of mitochondrial dysfunction, however,are not known. To examine these consequences, mitochondriallytransformed cells (cybrids) were created from AD patients or disease-freecontrols. Mitochondria from platelets were fused to $rho$ ⁰ cells created by depleting the human neuroblastoma line SH-SY5Yof its mitochondrial DNA (mtDNA). AD cybrids demonstrated a 52%decrease in electron transport chain (ETC) complex IV activitybut no difference in complex I activity compared with controlcybrids or SH-SY5Y cells. This mitochondrial dysfunction suggestsa transferable mtDNA defect associated with AD. ROS generationwas elevated in the AD cybrids. AD cybrids also displayed an increasedbasal cytosolic calcium concentration and enhanced sensitivityto inositol-1,4,5-triphosphate (InsP₃)-mediated release. Furthermore,they recovered more slowly from an elevation in cytosolic calciuminduced by the InsP₃ agonist carbachol. Mitochondrial calciumbuffering plays a major role after this type of perturbation. $beta$ -amyloid (25-35) peptide delayed the initiation of calcium recoveryto a carbachol challenge and slowed the recovery rate. Nerve growthfactor reduced the carbachol-induced maximum and moderated therecovery kinetics. Succinate increased ETC activity and partiallyrestored the AD cybrid recovery rate. These subtle alterationsin calcium homeostasis and ROS generation might lead to increasedsusceptibility to cell death under circumstances not ordinarilytoxic.
Key words: Alzheimer's disease; mitochondria; calcium; neurodegeneration; reactive oxygen species; nerve growth factor; $beta$ -amyloid

INTRODUCTION

Alzheimer's disease (AD) is a devastating, progressive dementia accounting for 50% of all dementias (Greenburg, 1994). Somefactors contributing to AD include $beta$ -amyloid precursor protein(APP) mutations, ApoE genotype, transmembrane proteins S182 andSTM2, reduced glucose transport, excitotoxins, head trauma, anddeficiencies in mitochondrial cytochrome c oxidase (COX or complexIV) activity (Parker et al., 1990b, 1994a,b; Parker, 1991; Chandrasekaranet al., 1992; Kish et al., 1992; Mutisya et al., 1994; Mattson,1995; Yanker, 1996; Davis et al., 1997). The idea of a mitochondrialcomponent to neurodegenerative diseases is not new, and it hasalso been proposed for Parkinson's disease and Guam Parkinsonism/DementiaComplex (Parker et al., 1990a, 1994a; Beal, 1995). The complexIV lesion resembles other electron transport chain (ETC) defectsknown to produce Leber's neuropathy and neuropathy-ataxia-retinitispigmentosa (Singh et al., 1989; Goto et al., 1990; Shoffner etal., 1990; Howell et al., 1991; Ortiz et al., 1993). In vivo complexIV inhibition with azide causes defects in learning and memoryand alters hippocampal potentiation (Bennett et al., 1992, 1996).COX dysfunction also increases free radicals, reduces energy stores,and disturbs amyloid metabolism (Gabuzda et al., 1994; Mutisyaet al., 1994; Smith et al., 1996; Davis et al., 1997). COX dysfunctionis associated with Down's syndrome; many Down's syndrome patientsdevelop AD (Prince et al., 1994; Busciglio and Yanker, 1995).Mutations in mitochondrial COX genes also seem to segregate withlate-onset AD (Davis et al., 1996, 1997).

Whether the mitochondrial defect resulting in decreased COX activity is a primary causative factor or a downstream effectof other factors remains unknown. Nevertheless, knowledge of thefunctional consequences of mitochondrial dysfunction is importantfor understanding the basis of selective neuronal vulnerability(Beal, 1995). Mitochondrial defects and decreased COX activityseem to be upstream relative to the selective neuronal loss inAD (Davis et al., 1997).

A novel technique for studying diseases associated with mitochondria was described by King and Attardi (1989). MitochondrialDNA (mtDNA)-depleted cells, termed $rho$ ⁰, were prepared by ethidium bromide treatment, and then thesecells were repopulated with exogenous mitochondria (King and Attardi,1989). These cytoplasmic hybrids (cybrids) enable in vitro comparisonof mitochondrial differences (Johns, 1996). Miller et al. (1996)produced $rho$ ⁰ cells starting from the human SH-SY5Y neuroblastoma line. Exogenousmitochondria were introduced by fusing human platelets with $rho$ ⁰ cells (Swerdlow et al., 1996). Although complex I activity wascomparable in the SH-SY5Y cells and in the AD and control cybrids,complex IV activity in the AD cybrids was reduced (Glasco et al.,1995).

Using these cybrids, we examined the functional consequences of a mitochondrial complex IV defect associated with AD. Thecomplex IV defect has subtle consequences, including an elevationin AD cybrid cytosolic calcium and a net difference in carbonylcyanide m-chlorophenylhydrazone (CCCP) releaseable mitochondrialcalcium stores. The most pronounced difference is a delay in thecalcium recovery rate of the AD cybrids after stimulation withthe inositol-1,4,5-triphosphate (InsP₃)-inducing agonist carbachol.

MATERIALS AND METHODS
Materials. ATP, ADP, and AMP standards for HPLC were prepared from Sigma (St. Louis, MO) reagents. A dimethylsulfoxide (DMSO)stock of CCCP (10 mM; Sigma) was used. The dilution factor forthe DMSO stock was 1:1000. Thus, the DMSO concentration in theworking solutions was small, and any effect it might have shouldbe minimal. A carbachol chloride stock (10 mM; Sigma) was madein Tyrode's solution, pH 7.3. The HEPES/Krebs/Ringer's solutionbuffer (HKRB) consisted of the following: 20 mM HEPES, 103 mMNaCl, 4.77 mM KCl, 0.5 mM CaCl₂, 1.2 mM MgCl₂, 1.2 mM KH₂PO₄,25 mM NaHCO₃, and 15 mM glucose in sterile water titrated to pH7.3. The succinate stock (5 mM; Sigma) was created in sterileHKRB. Mouse nerve growth factor (NGF) (2.5S) was obtained fromDr. Gene Johnson at the University of Washington (St. Louis, MO);a 10 µg/ml NGF stock was made in unbuffered saline. The amyloid $beta$ -protein (25-35) (lot no. B01028) and control amyloid $beta$ -protein(35-25) (lot no. SL817) were obtained from Bachem (King of Prussia,PA). A 0.5 mM aqueous-based stock solution of each amyloid $beta$ -proteinwas prepared 1-2 hr before experimentation; dilution of the stocksolution in medium was performed to achieve a working 40 µM concentrationof amyloid $beta$ -protein (Mattson et al., 1992).

Cell culture preparation. mtDNA-deficient $rho$ ⁰ cells, derived from the human SH-SY5Y neuroblastoma line, were obtained from MitoKorCorporation (San Diego, CA). The $rho$ ⁰ cells have no detectable mtDNA, no cyanide-inhibitable oxygenutilization, and no detectable complex I or cytochrome c oxidaseactivity; they are auxotrophic for pyruvate (Miller et al., 1996). $rho$ ⁰ cells were repopulated with platelet mitochondria from eithercontrol or AD patients through fusion in the presence of polyethyleneglycol (Davis et al., 1997). Untransformed cells were killed throughwithdrawal of pyruvate from the culture medium (Miller et al.,1996; Swerdlow et al., 1996). The surviving cells were termedmitochondrial cybrids (i.e., cytoplasmic hybrids).

AD and control cybrids were grown in DMEM (Life Technologies, Grand Island, NY) supplemented with 10% fetal bovine serum (Hyclone,Logan, UT). Cells were plated onto uncoated glass-bottom microwells(MatTek Corporation, Ashland, MA) for the calcium studies, T75tissue culture flasks (Costar Corporation, Cambridge, MA) forthe HPLC analysis, or 96-well tissue culture plates (Nunc, Roskilde,Denmark) for the reactive oxygen species (ROS) assays.

Enzymatic assays and determination of total cellular protein. Complex I (NADH:ubiquinone oxidoreductase) was determined asdescribed previously using the short chain ubiquinone analog coenzymeQ₁ (Eisai Pharmaceuticals, Tokyo, Japan) (Mutisya et al., 1994).Complex IV activities were determined as described earlier (Parkeret al., 1990b, 1994b; Swerdlow et al., 1996). All enzymatic activitiesare expressed as values normalized to total cellular protein (LowryProtein Assay; Pierce, Rockford, Illinois).

Adenine nucleotide measurement by HPLC ATP, ADP, and AMP levels of the cybrids were measured using anion-exchange HPLC (Meghjiet al., 1989). Recovery of the adenine nucleotide contents fromcells was in excess of 90% (Shryock et al., 1986). Cells wereharvested from confluent T75 flasks with an 80% HPLC grade methanol(J. T. Baker Chemical Company, Phillipsburg, NJ) and 0.5 mM EGTA(Sigma) solution at 70-75°C. The extract was then centrifuged,and the supernatant removed. Extracts were evaporated to drynessusing a vacuum desiccator. Samples were reconstituted in HPLCgrade water. An equal volume of a 1:4 mixture of heptane (Sigma)and freon (J. T. Baker) solution was added to each sample. Sampleswere then vortexed for 2 min and centrifuged to separate aqueousand organic layers. The upper aqueous layer contained the compoundsof interest, whereas the lower one contained unwanted lipids andorganic solvents.

For each sample, a 100 µl volume was injected into a weak anion-exchange column (Beckman 4.6 × 250 mm ZO; Beckman Instruments,San Ramon, CA). Buffer A was a 5 mM NH₄H₂PO₄ aqueous-based solution;buffer B was a 750 mM NH₄H₂PO₄ solution. Each buffer was titratedto pH 4.0 with solid sulfamic acid and passed through a 0.22 µMfilter. The gradient was linear from 0 to 100% of buffer B in30 min, followed by a 3 min hold at 100% of buffer B, and thena gradual reversal to 100% of buffer A for column reequilibration.The total flow rate was 1.6 ml/min. Complete run time was 64 min,and the analysis was completed at ambient temperature. A dry-packedprecolumn preceded the main analytical column. The absorbanceof the column effluent was measured at 254 nm by a Beckman SystemGold Chromatographer. The autosampler used to inject the sampleswas a Beckman model 506.

Nucleotide and nucleoside standards were prepared and run through the column to confirm peak identification. Quantitationof compounds was attained by comparing the integrated areas ofthe sample peaks with those of the standards. The bioenergeticstate of the cell was calculated using the following equation:[(ATP + 0.5 × ADP)/(ATP + ADP + AMP)] (Ankarcrona et al., 1995).

ROS assay. The ROS assay was modified from previously described techniques (Rosenkranz et al., 1992; Trayner et al., 1995;Miller et al., 1996; Swerdlow et al., 1996). Cells were platedat a density of 100,000 cells/well in 96-well tissue culture platesand allowed to grow for 24 hr in DMEM supplemented with 10% fetalbovine serum. The medium was then removed, and the cells wererinsed twice in HKRB. Cells were then incubated in a 30 µM solutionof 2 $'$ ,7 $'$ -dichlorodihydrofluorescein diacetate (H₂DCFDA) (MolecularProbes, Eugene, OR) for 2 hr during which time they were shieldedfrom light. Cells were again washed twice with HKRB, and thencells in each well were incubated in 200 µl of HKRB at 37°C for60 min. The H₂DCFDA fluorescence resulting from interaction ofthe dye with ROS was read using a Fluoroskan II (Flow Laboratories,McLean, VA) with the excitation and emission wavelengths set at485 and 538 nm, respectively.

Immediately after measurement of the H₂DCFDA fluorescence, a quantitative lactate dehydrogenase (LDH) absorbance assay wasperformed using a commercial LDH assay kit according to the manufacturer'srecommendations (Promega, Madison, WI). In brief, the assay involvescell lysis, release of LDH, and a 30 min coupled enzymatic assayresulting in the conversion of a tetrazolium salt into a red formazanproduct. Absorbance was read at 490 nm on an automated microplatereader, model EL311sx (Bio-Tek Instruments, Winooski, VT). TheLDH absorbance assay has been demonstrated to correlate with totalcell number (Moravec, 1994; Rhodes, 1996). The ratio of the H₂DCFDAfluorescence to the LDH absorbance was taken as the extent ofROS generation normalized to cell number.

Measurement of cytosolic calcium. Cells were washed twice in HKRB and loaded with 16 µM fura-2 AM (Molecular Probes), 0.0833%pluronic F-127 (Molecular Probes), and 1% fetal bovine serum for30 min at 37°C. Then, the cells were washed twice again in bufferand incubated at 37°C for 30 min, thereby permitting the cellsto hydrolyze completely the AM ester. Afterward, the cells wereready for calcium imaging. During the entire loading process andthereafter, the cells were shielded from ambient light.

Cytosolic calcium was measured using the fluorescent dye fura-2. Cells were imaged using a Zeiss Axiovert inverted microscopeequipped with a 20× objective (Carl Zeiss, Thornwood, NY) andC-Imaging version 2.0 software (Compix, Mars, PA). Excitationof the cells was performed at 340 nm for the bound form and 380nm for the unbound form; emission was measured by a photomultiplierat 510 nm (a 10 nm bandpass). Excitation by the 100 W Hg lampwas attenuated with a 1.0 neutral density filter. Sampling frequencywas performed at 1 Hz to avoid excessive bleaching of the fluorescentdye. Field diaphragms on the illumination and sampling ports servedto minimize background fluorescence. Regions of interest (n) weredefined to include one to three cells and excluded any area notcovered by a cell.

Calcium concentrations were computed from fluorescence intensity ratios using the following equation (Grynkiewicz et al.,1985):

where R is the F_{bound at
340nm}/F_{unbound at 380nm}, R_min is the ratio when all the dye is unbound to calcium, and R_max is theratio when all the dye is maximally bound to calcium. R_min wasdetermined using a 2 mM EGTA solution and found to be 0.55. Ina similar fashion, an R_max of 3.3 was determined using a 50 µMdigitonin solution. The K_d of 220 nM was computed using a calciumcalibration buffer kit (Molecular Probes), and all experimentswere conducted at 20-22°C. Cells were perfused with HKRB containing0.5 mM [Ca²⁺], pH 7.3.

Estimation of cytosolic calcium recovery rates. To determine the cytosolic calcium recovery rate after carbachol stimulation,the fluorescence ratio (r = F_{bound at
340nm}/F_{unbound at 380nm})decay was analyzed as a function of time. Linear regression wasperformed to achieve a best fit line to the ratio decay startingfrom the carbachol-induced maximum fluorescence ratio and spanningthe data to one of three endpoints as follows: (1) the point atwhich the cell achieved a stable fluorescence ratio baseline ifthe cell returned to an elevated baseline; (2) the point at whichthe cell attained the prestimulus fluorescence ratio if it recoveredto such an extent; or (3) the endpoint during a 10 min calciummicrofluorimetry recording period if the cell failed to achieveeither a stable baseline or the prestimulus value. In this process,the slope (dR/dt) was computed. Experimental values are reportedas the mean ± SEM. Mean Pearson correlation coefficients for thelinear regression in each group were 0.874 ± 0.020 (SH-SY5Y),0.973 ± 0.003 (control cybrid), and 0.903 ± 0.008 (AD cybrid).

RESULTS
Cybrid lines were created using mitochondria derived from four patients clinically diagnosed with AD and eight disease-free,age-matched controls. Individuals in the AD group met the NationalInstitute of Neurological Communicative Disorders and Stroke andthe Alzheimer's Diseases and Related Disorders Association criteriafor probable AD (McKhann et al., 1984). None of the AD patientswere believed to have alternative diagnoses to explain their dementia,and none displayed autosomal dominant, familial forms of AD. Controlsunderwent numerous neuropsychological evaluations and were foundto be dementia-free. Neither the AD nor control subjects had relatedsystems degenerations, drug-induced dementia, or an alternativeneurodegenerative disorder. Participation of AD and control subjectsas donors of mtDNA was approved by the Institutional Review Board.

In this sample, AD and control subjects were of comparable age and had similar complex I activity (i.e., for both age andcomplex I activity, p $>>$ 0.05 in unpaired t tests of AD and controlsubjects); however, the AD subjects had a 52% decrease in complexIV activity (p < 0.003; unpaired t test) compared with controls.Table 1 details the ETC activities of the cybrid cells derivedfrom the 12 subjects. This series was selected randomly from alarger one that also displayed a similar decrease in complex IVactivity associated with AD subjects (Davis et al., 1997).

Table 1. Attributes of Alzheimer's disease and disease-free, age-matched subjects

Patient Age (years) Patient (gender) Complex I activity (nmol · min¹ · mg¹) Complex IV activity [1/(sec × mg)]

Disease-free control 1 78 Male 39.6 0.0954

Disease-free control 2 51 Female 34.9 0.0620

Disease-free control 3 46 Female 40.9 0.0727

Disease-free control 4 68 Female 29.6 0.0625

Disease-free control 5 70 Male 38.9 0.0785

Disease-free control 6 77 Female 35.7 0.0656

Disease-free control 7 54 Female 29.2 0.0790

Disease-free control 8 76 Male 35.7 0.0889

Alzheimer's disease 1 67 Male 30.5 0.0174

Alzheimer's disease 2 71 Male 35.0 0.0571

Alzheimer's disease 3 77 Male 35.3 0.0485

Alzheimer's disease 4 81 Male 33.4 0.0213

The subjects are identified by disease or disease-free and number, and each subject's age (years), gender (male/female), complexI activity (nmol · min¹ · mg¹), and complex IV activity (sec¹/mg) are listed.

Cytosolic calcium
Resting or basal cytosolic calcium concentrations were determined for the SH-SY5Y cell line and the AD and control cybridsunder two experimental conditions (Fig. 1). For the calcium experimentsperformed on the cybrids, the results are expressed as the meansfrom four AD or eight control cybrid lines. The mean for eachcybrid line is based on multiple, independent observations ofsingle regions of interest. Regions of interest used for fluorescenceimaging each contained approximately one to three cells and excludedacellular areas. For the SH-SY5Ys, basal cytosolic calcium ina saline buffer was 132 ± 11 nM (mean ± SEM; n = 11), and controlcybrids in saline buffer had a cytosolic calcium concentrationof 143 ± 12 nM (n = 8; three to four observations per controlcybrid line). AD cybrids, however, had a significantly elevatedvalue of 192 ± 10 nM (n = 4; eight to nine observations per cybridline) (Fig. 1) (p < 0.05), compared with either the control cybridsor the parent SH-SY5Y cell line as evaluated by Fisher's protectedleast significant difference (PLSD) ANOVA (StatView version 4.51;Abacus Concepts, Berkeley, CA).
Fig. 1. Basal cytosolic calcium concentrations for SH-SY5Y cells and control and AD cybrids were measured under two different conditions.Calcium was measured using fura-2, and values represent the meanof the SH-SY5Y cells, four AD cybrid lines, and eight controlcybrid lines. An asterisk indicates a statistically significantdifference (p < 0.05) between values indicated by the brackets.Under saline buffer conditions, AD cybrids demonstrated elevatedcytosolic calcium compared with either the SH-SY5Y line or thecontrol cybrids. NGF caused a reduction in cytosolic calcium forthe AD cybrids but an elevation for the SH-SY5Y cells.
[View Larger Version of this Image (35K GIF file)]

Exposure of the cell lines to 10 ng/ml of 2.5S NGF for 24 hr increased the cytosolic calcium of the SH-SY5Y cells relativeto the equivalent cell type in a saline-buffered medium (Fig.1) (p < 0.05; unpaired t test). Exposure of the AD cybrids toNGF, however, decreased cytosolic calcium to 134 ± 16 nM (n =4; four to five observations per AD cybrid line) compared withthe AD cybrids in saline-buffered medium (Fig. 1) (p < 0.05; unpairedt test). Treatment of SH-SY5Y cells with 40 µM A $beta$ (25-35), a biologicallyactive domain of the amyloid $beta$ -protein, for 1 hr resulted in anelevation of cytosolic calcium to 195 ± 35 nM (n = 6; p < 0.025).Similar amyloid treatments in control and AD cybrids resultedin no statistically significant differences as compared with ADand control cybrids under saline buffer conditions. Finally, exposureof all the cell lines to 40 µM A $beta$ (35-25), an inactive control,for 1 hr resulted in no changes in cytosolic calcium concentrations.

Cellular energy state
Basal ATP, ADP, and AMP levels were measured in the SH-SY5Ys and cybrids to determine whether complex IV deficiencies of ADcybrids resulted in differences in the bioenergetic status ofthe cells. Energy quotient values (i.e., [ (ATP + 0.5 × ADP)/(ATP+ ADP + AMP) ]) for the cell lines were as follows: SH-SY5Y =0.64 ± 0.06 (mean ± SEM; n = 4); AD cybrid = 0.66 ± 0.05 (n =4); and control cybrid = 0.64 ± 0.02 (n = 6), where n is the numberof HPLC samples for the SH-SY5Ys and the number of cybrid linesanalyzed for the ADs and controls (Fig. 2). The HPLC results arebased on multiple, replicative experiments in which each AD cellline was analyzed twice, the parent SH-SY5Y cells were analyzedfour times, and six of eight control cybrid lines were analyzedonce. Thus, the basal bioenergetic states of the SH-SY5Ys andthe AD and control cybrids were similar (i.e., all p values $>>$ 0.05 by Fisher's PLSD ANOVA). Hence, under basal conditions, mtDNAfrom AD patients has a minimal impact on cellular energy storesin this cybrid model system.
Fig. 2. Basal energy quotients (i.e., [(ATP + 0.5 × ADP)/(ATP + ADP + AMP)]) were measured using anion-exchange HPLC. Energy quotientsfor all cell types were comparable.
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Basal ROS production
Basal ROS production was assessed for the AD and control cybrid cell lines to determine the impact of a complex IV deficiencyon ROS production. AD and control cybrid ROS production was computedas the quotient of the relative H₂DCFDA fluorescence over thecell number normalization factor of LDH absorbance. The mean valuesfor all AD and control cybrid lines were 15.1 ± 0.3 (mean ± SEM;n = 4) and 11.1 ± 0.2 (n = 8), respectively (Fig. 3). These ROSvalues are based on multiple, replicative experiments of eachcybrid line. Thus, AD cybrids with their complex IV defect demonstrateda 36% increase in basal ROS production (p < 0.05; unpaired t test).
Fig. 3. Cellular ROS production was determined as the ratio of DCFDA fluorescence normalized per cell number by the LDH absorbance.Under basal conditions, AD cybrid lines showed an increased productionof ROS (*p < 0.05).
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Basal mitochondrial calcium sequestration
With significant differences in basal cytosolic calcium concentrations and ROS but none in the basal bioenergetic states betweenAD and control cybrids, we assessed the amount of calcium sequesteredin mitochondria. Cells were exposed to 10 µM CCCP, a protonophorethat dissipates the mitochondrial membrane potential, releasessequestered mitochondrial calcium stores, and irreversibly preventsmitochondrial calcium uptake. Rapid application of CCCP to cellsincubated in HKRB caused the fluorescence ratio of bound to unboundfura-2 to increase transiently in both the AD and control cybrids(Fig. 4A). The CCCP-induced ratio maxima for the AD and controlcybrids were 1.75 ± 0.034 (n = 4) and 1.72 ± 0.060 (n = 8), respectively.In terms of calcium concentrations rather than fluorescence ratios,the CCCP-induced peaks in cytosolic calcium in the AD and controlcybrids were 369 ± 13 nM (n = 4) and 361 ± 38 nM (n = 8), respectively(Fig. 4B). Both the fura ratios and the cytosolic calcium valuesare based on five to six observations for each AD cybrid lineand three to four observations for each control cybrid line. Thedifference between the CCCP-induced cytosolic calcium peak ofthe cell and its basal cytosolic calcium concentration is attributable,at least in part, to release of calcium sequestered in the mitochondriaof the cell. Therefore, because the AD cybrids have a higher basalcytosolic concentration but an overall CCCP-induced cytosoliccalcium peak comparable to the control cybrids, the AD cybridmitochondria may carry a smaller load of sequestered calcium thanthe control cybrid mitochondria (p < 0.01; unpaired t test). Theaddition of CCCP to cells that had not been loaded with fura-2resulted in no change in intrinsic fluorescence.
Fig. 4. Cytosolic calcium after a CCCP stimulus. A, Both AD and control cybrid lines in a saline buffer were challenged with 10 µMCCCP in HKRB at the point indicated by the arrow. These tracesare representative fura-2-based fluorescence ratios as a functionof time for single regions of interest. CCCP-induced calcium elevationswere transient. Only prestimulus baselines and subsequent stimulatedcalcium elevations to respective maxima are shown in these truncatedtraces. B, The CCCP-induced peak calcium levels for the AD (n= 4) and control (n = 8) cybrid lines were comparable; however,the amount of calcium sequestered in the mitochondria is actuallythe difference between the CCCP-induced calcium maximum and thebasal cytosolic calcium concentration. Although CCCP-induced peaksare comparable between AD and control cybrids, the basal calciumconcentration of AD cybrids is greater than control. Note thedifference in prestimulus fura ratios indicative of the substantialbasal cytosolic calcium difference between ADs and controls inA. Thus, under basal conditions, AD cybrid mitochondria sequesterless calcium (p < 0.01).
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Mitochondrial-based cytosolic calcium recovery kinetics
In the SH-SY5Y and cybrid cell lines, carbachol, an InsP₃-inducing cholinergic agonist, causes a transient elevation in cytosoliccalcium followed by a recovery generally to a stable baseline(either to a basal, prestimulus level or a somewhat elevated calciumconcentration) over a time period of ~10 min. Examination of calciumhandling in the cybrid lines after a carbachol challenge revealedsubstantial differences. In particular, the derivatives of thefura fluorescence ratio (d(F_{bound at
340nm}/F_{unbound at 380nm})/dt)recoveries differed substantially between AD cybrids and controls.The recovery slopes of the AD and control cybrids are $-$ 0.00055± 0.000054 sec¹ (mean ± SEM; n = 4) and $-$ 0.0046 ± 0.00015 sec¹ (n = 8), respectively (Fig. 5) (p < 0.01; unpaired t test). Figure5 illustrates the recovery slopes for each of four AD and eightcontrol cell lines as indicated by a circle. Each circle representsa mean of six to seven observations per control cell line andsix to eight observations per AD cell line. The error bars inFigure 5 indicate a range of ±2 SD. The apparently narrow distributionof recovery slopes within either the group of AD cybrid linesor the controls coupled with the obvious intergroup (i.e., ADsvs controls) differences (Fig. 5) prompted the statistical poolingof recovery slopes within groups for the remainder of the analysis.
Fig. 5. Cytosolic calcium recovery slopes after a carbachol stimulus. Four AD cybrid lines and eight control lines were stimulatedwith 100 µM carbachol, and the mean fura fluorescence recoveryslope after attainment of peak fluorescence for each cell lineis depicted by a circle. Each AD cybrid line indicated by thecircle is based on six to eight observations; each control lineis the mean of six to seven observations. The error bars indicate±2 SD from the overall group mean. The recovery slopes of theAD cybrid and control groups differ substantially (*p < 0.01;unpaired t test).
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Representative fura-2 fluorescence ratio (F_{bound at
340nm}/ F_{unbound at 380nm}) traces as a function of time after a carbacholstimulus are illustrated in Figures 6A, 7A, and 8A. Peak cytosoliccalcium concentrations after stimulation with 100 µM carbacholfor the cell lines were as follows: SH-SY5Y = 401 ± 26 nM (n =12); AD cybrid = 428 ± 11 nM (n = 28); and control cybrid = 381± 14 nM (n = 28). Here and for the remainder of Results, n representsthe number of regions of interest; approximately equal numbersof interest regions were examined per AD or control cybrid linein multiple, replicative experiments. Carbachol has approximatelythe same initial effect on cytosolic calcium in the SH-SY5Ys andcontrol cybrids; however, the carbachol-induced peak in the ADcybrids was slightly elevated compared with control cybrids (p= 0.014; unpaired t test).
Fig. 6. SH-SY5Y calcium recovery kinetics after a carbachol stimulus. A, SH-SY5Y cells were challenged with 100 µM carbachol (indicatedby arrow) in a saline buffer ( $---$ ). As noted, cells were uninhibited(actual solid line trace), pretreated with NGF (10 ng/ml of 2.5Sfor 24 hr), or exposed to $beta$ -amyloid (25-35) or its control (35-25)peptide at 40 µM for 1 hr before stimulus. The trace was recordedduring carbachol stimulation of a single region of interest incubatedin saline buffer (i.e., 1-3 cells) and is representative of thewhole. Both average recovery slope and calcium maximum for NGF-treatedcells (- - -) were reduced. $beta$ -amyloid (25-35)-exposed cells (- - -)demonstrated delayed onset of recovery (note the initial plateau)and a decreased recovery slope. $beta$ -amyloid (35-25) incubation (- · - · -)had no significant effect compared with saline control. B, Meanrecovery derivatives of the fura-2 fluorescence ratio (d(F_{bound at
340nm}/F_{unbound at
380nm})/dt)until attainment of a stable baseline are depicted. Recovery inthe presence of either NGF or $beta$ -amyloid (25-35) was significantlyslowed (*p < 0.05).
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Fig. 7. Control cybrid calcium recovery kinetics after a carbachol stimulus. A, Control cybrids were challenged with 100 µM carbachol(indicated by arrow) in a saline buffer, and as noted, some werealso exposed to the following before stimulus: 10 ng/ml of 2.5SNGF for 24 hr (- - -), 40 µM $beta$ -amyloid (25-35) for 1 hr (- - -),or 40 µM $beta$ -amyloid (35-25) for 1 hr (- · - · -). The solid linetrace ( $---$ ) is a representative single region of interest (i.e.,1-3 cells) fura-2 ratio recording of control cybrids incubatedin a saline buffer responding to a carbachol stimulus. The linesare indicative of the mean recovery slopes for the control cybridsunder particular pharmacological conditions. Again, note the decreasedcalcium peak with NGF treatment and the delayed initiation ofrecovery in $beta$ -amyloid (25-35)-treated control cybrids. B, Recoveryderivatives of the fura-2 fluorescence ratio (d(F_{bound at
340nm}/F_{unbound at
380nm})/dt)until attainment of a stable baseline are detailed. Control cybridrecovery was reduced with both NGF and $beta$ -amyloid (25-35) treatment(*p < 0.05).
[View Larger Version of this Image (17K GIF file)]

Fig. 8. AD cybrid calcium recovery kinetics after a carbachol stimulus. A, AD cybrids with reduced complex IV activity were challengedwith 100 µM carbachol in a saline buffer ( $---$ ), and some were alsoexposed to other pharmacological agents such as 10 ng/ml of NGF(- - -), 40 µM $beta$ -amyloid (25-35) (- - -), 40 µM $beta$ -amyloid (35-25)(- · - · -), 5 mM succinate (· · ·), or NGF and succinate (- · - · -).The trace represents fura fluorescence ratio measurements of asingle region of interest (i.e., 1-3 cells) stimulated with carbachol.The other lines are indicative of the mean recovery slopes forthe AD cybrids under particular pharmacological conditions. Again,NGF treatment alone significantly reduced the carbachol-inducedcalcium peak, and $beta$ -amyloid (25-35) exposure delayed the initiationof recovery (note the initial plateau recovery response). Thecarbachol-induced peak calcium concentration in the AD cybridsis slightly larger than in controls (p < 0.05); AD recovery kineticsare much slower than controls (Fig. 6A) (p < 0.05). B, Recoveryderivatives of the fura-2 fluorescence ratio until attainmentof a stable baseline are detailed. AD cybrid recovery was notsignificantly reduced by either $beta$ -amyloid (25-35) or $beta$ -amyloid(35-25). NGF alone was able to increase the recovery rate by 186%.Similarly, succinate increased the recovery kinetics by 165%.Succinate and NGF combined resulted in a 313% increase in thecalcium recovery rate (*p < 0.05).
[View Larger Version of this Image (19K GIF file)]

Although the initial cytosolic calcium maxima induced by carbachol were only slightly different, the rate of recovery of cytosoliccalcium to a stable baseline was much slower in the AD cybridsas compared with the control cybrids or the SH-SY5Ys (both p values< 0.0001 by Fisher's PLSD ANOVA). The derivatives of the fluorescenceratio (d(F_{bound at
340nm}/F_{unbound at 380nm})/dt) recoveries werethe following: AD = $-$ 0.00055 ± 0.000046 sec¹ (n = 28); control = $-$ 0.0046 ± 0.00018 sec¹ (n = 55); and SH-SY5Y = $-$ 0.0047 ± 0.00086 sec¹ (n = 8). All slopes were of comparably good fit as indicatedby similar Pearson correlation coefficients. These uninhibited,saline control recovery rates are depicted graphically in Figures6, 7, 8. After carbachol exposure, the cytosolic calcium recoveryoccurred at a rate 88% slower in the AD cybrids than in eitherof the other two cell types.

Cytosolic calcium recovery kinetics after NGF treatment
NGF has been shown to stabilize intracellular calcium and may have a therapeutic effect in AD (Mattson et al., 1993b; Olson,1993). To examine the effect of NGF on calcium handling in thesecells, they were treated with 10 ng/ml of 2.5S nerve growth factorfor 24 hr. Exposure to NGF decreased the overall carbachol-inducedcytosolic calcium peak in all cell types. The carbachol-inducedcalcium maxima for NGF-treated cells were as follows: SH-SY5Y= 366 ± 34 nM (n = 4); AD cybrid = 309 ± 21 nM (n = 17); and controlcybrid = 357 ± 14 nM (n = 14).

The reduction in peak calcium with NGF exposure was not the only change in cellular calcium handling. NGF-treated SH-SY5Ycells demonstrated a decrease in the fluorescence recovery slopeto $-$ 0.0031 ± 0.0014 (n = 4) (p = 0.013 by Fisher's PLSD ANOVA)(Fig. 6). Similarly, the recovery slope for NGF-treated controlcybrids decreased to $-$ 0.0020 ± 0.00014 (n = 37) sec¹ (p < 0.0001) (Fig. 7). AD cybrids treated with NGF, however,experienced an increase in the recovery slope to $-$ 0.0016 ± 0.00017sec¹ (n = 16) (p = 0.0016) (Fig. 8). Taken together, the decreasein calcium maxima and the similarity of calcium recovery ratesbetween control and AD cybrids indicate that NGF moderated cellularcalcium handling mechanisms.

Cytosolic calcium recovery kinetics after $beta$ -amyloid exposure
$beta$ -amyloid has been linked to disturbances in calcium homeostasis, mitochondrial dysfunction and AD (Mattson et al., 1992;Gabuzda et al., 1994; Yanker, 1996). Therefore, the interactionof $beta$ -amyloid with calcium handling in AD mitochondrial cybridswith a known ETC dysfunction, control cybrids, and SH-SY5Y cellswas examined. All cell lines were exposed to 40 µM $beta$ -amyloid (25-35)or its control $beta$ -amyloid (35-25) for 1 hr before carbachol challenge.This concentration of $beta$ -amyloid (25-35) has previously been shownto destabilize neuronal calcium homeostasis (Mattson et al., 1992).With either peptide, the overall carbachol-induced peak was thesame as for saline control conditions. Exposure to the active $beta$ -amyloid (25-35) resulted in a delay in the initiation of calciumrecovery in all cell types. The mean delays in initiation of calciumrecovery were as follows: SH-SY5Y = 32 ± 19 sec (n = 6); AD cybrids= 108 ± 13 sec (n = 52); and control cybrids = 27 ± 8 sec (n =40) (Figs. 6A, 7A, 8A). The delay in initiation of calcium recoveryobserved in the AD cybrids is much greater than in either theSH-SY5Y cells or the control cybrids (p < 0.0001 by Fisher's PLSDANOVA).

As for the recovery slopes after initiation of calcium recovery, active $beta$ -amyloid (25-35) slowed the rate of recovery in boththe SH-SY5Y cells and the control cybrids but had no statisticallysignificant effect on the AD cybrids (Figs. 6B, 7B, 8B). Afterthe horizontal phase of the fluorescence response, which has aslope of zero, the recovery slope for the remainder of the responseof the $beta$ -amyloid (25-35)-treated SH-SY5Y cells was reduced by83% to $-$ 0.00081 ± 0.00018 sec¹ (n = 6). For $beta$ -amyloid (25-35)-treated control cybrids, the recoveryslope was reduced by 76% to $-$ 0.0011 ± 0.000065 sec (n = 40). In all of the cell lines, the control $beta$ -amyloid (35-25)did not affect either the initiation of recovery or the recoveryrate after initiation (Figs. 6, 7, 8).

Effect of the complex II substrate succinate on the recovery rate
The relationship between reduced ETC activity and cellular handling of calcium was examined further by attempting to increaseETC activity. Excess succinate, a substrate for complex II, hasbeen shown to support ETC activity (Kane et al., 1975; Melnickand Schiller, 1985; Hekman et al., 1988; Takehara et al., 1995).Therefore, the effect of 5 mM succinate on mitochondrial calciumbuffering was examined in mitochondrial-defective AD cybrid lines.

Succinate treatment improved the rate of recovery in cytosolic calcium after a carbachol challenge. The recovery slope forthe uninhibited AD cybrids in the presence of succinate was $-$ 0.0014± 0.00013 sec¹ (n = 37), whereas that of the ADs without succinate was only $-$ 0.00055 ± 0.000046 sec¹ (n = 28) (Fig. 8). Hence, the recovery rate in succinate-treatedAD cybrids occurred 165% more quickly than in untreated AD cybrids(p = 0.0005; Fisher's PLSD ANOVA). Succinate addition along withNGF further improved the rate of recovery of AD cybrids by 313%relative to saline-buffered ones (p < 0.0001; n = 28) (Fig. 8).

DISCUSSION
Decreased mitochondrial complex IV activity has definite functional consequences in terms of calcium handling and ROS production.Basal cytosolic calcium values in the SH-SY5Y cells and controlcybrids were consistent with values reported previously (Naaralaet al., 1993). Thus, the process of creating the cybrid linesby itself did not alter normal cytosolic calcium. The elevationin basal cytosolic calcium exhibited by the AD cybrids must resultfrom mitochondrial dysfunction.

As for the increased ROS production in AD cybrids, cells with complex I dysfunction have demonstrated increased ROS production(Swerdlow et al., 1996). Elevated calcium, which was observedin the AD cybrids, has been shown to increase free radicals (Dykens,1994). Inhibition of complex IV increases ROS production in SH-SY5Ys(Miller et al., 1996). Others have reported increased ROS productionor damage in tissues from AD patients (Richardson, 1993; Zhouet al., 1995; Richardson et al., 1996; Smith et al., 1996). Mitochondrialfunction, calcium homeostasis, and ROS production seem intimatelyassociated, and an imbalance of one of these may have grave consequences(Beal, 1992).

Resting mitochondrial calcium reportedly is ~200 nM, and perturbations have been shown to raise this concentration (Rizzutoet al., 1992). Previous research has demonstrated mitochondrialsite specificity for CCCP (Thayer and Miller, 1990; Friel andTsien, 1994; Buttgereit and Brand, 1995; Park et al., 1996). Becausethe intramitochondrial calcium concentration is usually largerthan that in the cytosol, CCCP application causes a transientincrease in cytosolic calcium and a decrease in mitochondrialcalcium (Biscoe et al., 1989; Simpson and Russell, 1996). We observedan increase in cytosolic calcium with CCCP exposure to all ofour cell lines.

Mitochondria contributed to the buffering of an ~400 nM Ca²⁺ transient induced by carbachol in SH-SY5Ys and cybrid lines. InsP₃agonists increase cytosolic calcium through release of intracellularstores and influx (Drummond and Fay, 1996; Simpson et al., 1996;Babcock et al., 1997). Mitochondria play a major role in regulationand return to homeostasis after such a perturbation (Rizzuto etal., 1994; Jouaville et al., 1995; Simpson and Russell, 1996).In fact, mitochondrial calcium rapidly and transiently increasesafter agonist-induced InsP₃ generation (Rizzuto et al., 1994).The carbachol-induced peak calcium transient is comparable tothe 450-550 nM Ca²⁺ range at which mitochondria are believed to play a bufferingrole in dorsal root ganglion neurons or chromaffin cells (Werthand Thayer, 1994; Herrington et al., 1996). Mitochondria can rapidlyand significantly accumulate calcium from intra- or extracellularsources; they limit the exposure of a cell to high cytosolic calciumlevels (Duchen et al., 1990; White and Reynolds, 1995).

The source and amount of the calcium, proximity of the perturbation relative to the mitochondria, the mediator of calciumrelease, the temporal behavior of the calcium change, and theoverall bioenergetic state of a cell seem to influence the extentof mitochondrial buffering (Ghosh and Greenberg, 1995; White andReynolds, 1995; Drummond and Fay, 1996). For instance, rapid uptakeand modulation of InsP₃-mediated calcium by mitochondria dependson the proximity of the mitochondria to the releasing channels(Camacho and Lechleiter, 1993; Rizzuto et al., 1993; Jouavilleet al., 1995). InsP₃-mediated calcium release is buffered moreeffectively by mitochondria than increases caused by other stimuli(Donnadieu and Bouruignon, 1996; Simpson and Russell, 1996; Sheehanet al., 1997). Mitochondria in the SH-SY5Y cells and the cybridsderived from them contributed to the basal homeostasis and bufferingof InsP₃-mediated perturbations.

AD cybrids seldom attained a timely recovery to prestimulus cytosolic calcium levels. This delayed recovery could increasecytosolic, mitochondrial, and nuclear calcium, alter cellularexcitability and signaling, and ultimately lead to apoptosis (Nicoteraand Orrenius, 1992; Brini et al., 1993, 1994; Richter, 1993; Dykens,1994; Ghosh and Greenberg, 1995; Oshimi and Miyazaki, 1995; Khanet al., 1996; Simpson and Russell, 1996; Tong et al., 1996).

Fibroblasts from AD patients have decreased calcium uptake and increased calcium content (Peterson et al., 1985; Petersonand Goldman, 1986). AD fibroblasts have an increased cytosoliccalcium response to InsP₃ formation agonists (Peterson et al.,1986, 1988; Huang et al., 1991; McCoy et al., 1993; Etcheberrigarayet al., 1994; Ito et al., 1994). These reports are consistentwith enhancement of InsP₃-mediated calcium release in AD cybrids.Kumar et al. (1994) demonstrated decreased calcium uptake in mitochondriafrom AD fibroblasts. That report is consistent with our observationthat AD cybrid mitochondria carry a smaller load of sequesteredcalcium, as demonstrated by the CCCP experiments. The enhancedcalcium release mediated by InsP₃ along with the elevated basalcytosolic calcium and decreased mitochondrial calcium sequestrationsuggest that other cellular components (e.g., endoplasmic reticulum)are playing a larger role in calcium handling in the AD cybrids.

SH-SY5Y cells and control cybrids exposed to $beta$ -amyloid (25-35) exhibited decreased recovery rates comparable to those of uninhibitedAD cybrids. APP has already been shown to decrease complex IVactivity and cause other mitochondrial abnormalities (Askanaset al., 1996). The fact that $beta$ -amyloid (25-35) exposure did notproduce an additive effect in the AD cybrids suggests that maximalcomplex IV-induced delay in calcium recovery may be attained withthe 52% decrease. Moreover, the amyloid metabolism of these complexIV inhibited cells may already be altered in a manner adverseto calcium handling (Gabuzda et al., 1994) (R. E. Davis, unpublisheddata).

NGF partially rectified the calcium handling problems demonstrated by the AD cybrids. NGF protects neurons against hypoxic,hypoglycemic, and excitotoxic damage in vitro and ischemia invivo (Cheng and Mattson, 1991; Shigeno et al., 1991; Mattson andCheng, 1993; Mattson et al., 1993a,c). SH-SY5Y cells possess functionaltrkA receptors; NGF can differentiate SH-SY5Y cells (Baker etal., 1989; Poluha et al., 1995). NGF may stabilize calcium homeostasisby altering calcium binding proteins, modifying receptor function,restoring mitochondrial transmembrane potential, inducing Bcl-2,and preventing release of cytochrome c from mitochondria, or ahost of other mechanisms (Thoenen and Barde, 1980; Mattson etal., 1993c; Kluck et al., 1997; Yang et al., 1997).

The delayed calcium recovery inherent in the AD cybrids was partially rectified by succinate addition. The recovery observedwith succinate could result from a partial restoration of mitochondrialmembrane potential or increased ATP production. The effect ofsuccinate provides compelling evidence of a link between mitochondrialbuffering and function. This is surprising given the comparablebasal bioenergetics of the cybrids; however, similar basal bioenergeticstates do not preclude the possibility that AD cybrids might failto keep up under conditions of high energy demand. Treatment withNGF and succinate produced a further improvement in calcium recoverykinetics, indicating that they are not working solely via identicalmechanisms. This study is the first to demonstrate mitochondrial-basedfunctional consequences associated with AD in the context of aneuronal-like cell and the transferability of these consequenceswith the mitochondrial cybrid model.

These studies add weight to the connection between mitochondrial dysfunction and AD (Arispe et al., 1994; Cotman et al., 1994;Huang et al., 1994; Mattson, 1994). Sustained changes in cytosoliccalcium and ROS production related to mitochondrial impairmentcould serve as a final common pathway for the neuropathologicalchanges observed in AD (Gotz et al., 1994; Khachaturian, 1994;Beal, 1996). Excess calcium can damage cellular proteins and membranesthrough protease activation, endonuclease induction, and ROS production.It can also diminish early gene expression and inactivate irreversiblykey enzymes (Lai et al., 1988; Siman and Noszek, 1988; Carrollet al., 1992; Lipton et al., 1993; Verity, 1993; Khodarev andAshwell, 1996). ROS could damage mtDNA, which is prone to mutation(Beal, 1995).

Mitochondrial dysfunction has also been reported to alter amyloid metabolism. Azide-induced COX inhibition has been shownto change the processing of the APP and induce production of anamyloidogenic derivative of APP (Gabuzda et al., 1994). Hence,mitochondrial dysfunction could contribute to the amyloidosisobserved in AD. Amyloidosis could further destabilize calciumhomeostasis and facilitate excitotoxicity (Mattson et al., 1992;Yanker, 1996). Moreover, ultrastructural damage to the Golgi apparatusand mitochondria is observed with exposure to $beta$ -amyloid (Behlet al., 1994a,b). Expression of a presenilin-1 mutation linkedto an autosomal dominant form of AD exaggerates calcium responsesto carbachol and enhances apoptotic vulnerability to $beta$ -amyloid(Guo et al., 1996). Thus, familial forms of AD associated withpresenilin-1 or $beta$ -amyloid mutations and sporadic forms of AD withmitochondrial dysfunction and mtDNA defects seem to exhibit similarcalcium homeostasis disturbances that may lead to a common ADneuropathology.

Whether mtDNA defects in genes encoding for complex IV are a proximal or distal event in late-onset AD is unclear at present(Davis et al., 1997). Nevertheless, mitochondrial dysfunctionand its functional consequences probably contribute to the pathogenesisof sporadic AD, which likely results from numerous causes (St.George-Hyslop et al., 1990). Neuronal survival may depend on adelicate balance between nuclear and mitochondrial genome stability,mitochondrial function, calcium homeostasis, ROS production, amyloidmetabolism, and cell signaling (Mattson, 1995; Beal, 1996; Yanker,1996).

FOOTNOTES

Received Jan. 15, 1997; revised March 5, 1997; accepted April 2, 1997.

We thank Dr. Scott R. Vandenberg, Director of Neuropathology, and Dr. George E. Vandenhoff, Diabetes Core Laboratory, Universityof Virginia. The $rho$ ⁰ cells were a gift of MitoKor Corporation (San Diego). Specialthanks also to Drs. John A. Jane and Gregory A. Helm of the Universityof Virginia Department of Neurosurgery for advice, guidance, encouragement,and support.

Correspondence should be addressed to Dr. J. B. Tuttle, Box 230, Health Sciences Center, University of Virginia, Charlottesville,VA 22908.

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