Diets Enriched in Foods with High Antioxidant Activity Reverse Age-Induced Decreases in Cerebellar beta -Adrenergic Function and Increases in Proinflammatory Cytokines

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The Journal of Neuroscience, July 15, 2002, 22(14):6114-6120

Diets Enriched in Foods with High Antioxidant Activity Reverse Age-Induced Decreases in Cerebellar $beta$ -Adrenergic Function and Increases in Proinflammatory Cytokines
Carmelina Gemma¹^,², Michael H. Mesches³^,⁴, Boris Sepesi⁴, Kevin Choo⁴, Douglas B. Holmes⁴, and Paula C. Bickford¹^,²
¹ James A. Haley Veterans Affairs Medical Center, Tampa, Florida 33612, ² Center for Aging and Brain Repair, Department of Neurosurgery, University of South Florida College of Medicine, Tampa, Florida 33612, ³ Denver Veterans Affairs Medical Center, Denver, Colorado 80220, and ⁴ Department of Pharmacology, University of Colorado Health Sciences Center, Denver, Colorado 80262

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Antioxidants and diets supplemented with foods high in oxygen radical absorbance capacity (ORAC) reverse age-related decreasesin cerebellar $beta$ -adrenergic receptor function. We examined whetherthis effect was related to the antioxidant capacity of the foodsupplement and whether an antioxidant-rich diet reduced the levelsof proinflammatory cytokines in the cerebellum. Aged male Fischer344 rats were given apple (5 mg dry weight), spirulina (5 mg),or cucumber (5 mg) either in 0.5 ml water by oral gavage or suppliedin the rat chow daily for 14 d. Electrophysiologic techniquesrevealed a significant decrease in $beta$ -adrenergic receptor functionin aged control rats. Spirulina reversed this effect. Apple (afood with intermediate ORAC) had an intermediate effect on cerebellar $beta$ -adrenergic receptor physiology, and cucumber (low ORAC) hadno effect, indicating that the reversal of $beta$ -adrenergic receptorfunction decreases might be related to the ORAC dose. The mRNAof the proinflammatory cytokines tumor necrosis factor- $alpha$ (TNF $alpha$ )and TNF $beta$ was also examined. RNase protection assays revealed increasedlevels of these cytokines in the aged cerebellum. Spirulina andapple significantly downregulated this age-related increase inproinflammatory cytokines, whereas cucumber had no effect, suggestingthat one mechanism by which these diets work is by modulationof an age-related increase in inflammatory responses. Malondialdehyde(MDA) was measured as a marker of oxidative damage. Apple andspirulina but not cucumber decreased MDA levels in the aged rats.In summary, the improved $beta$ -adrenergic receptor function in agedrats induced by diets rich in antioxidants is related to the ORACdose, and these diets reduce proinflammatory cytokinelevels.

Key words: aging; cerebellum; cytokines; antioxidants; norepinephrine; inflammation

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Impaired antioxidant defense mechanisms and increases in reactive oxygen species and reactive nitrogen species are postulatedto be causative factors in aging-related functional declines andin neurodegenerative diseases (Harman, 1956; Leibovitz and Siegel,1980; Ames et al., 1993). Increasing evidence suggests that inflammatoryprocesses are linked to oxidative damage in the CNS. Injectionof the antioxidant enzyme superoxide dismutase decreases inflammationin some animal model systems. Antioxidants such as vitamins E,C, and $beta$ -carotene enhance some parameters of immune function whenadded to isolated immune cells in vitro or when given as supplementsto humans or animals in vivo (Han and Meydani, 2000). Despiteextensive evidence of the anti-inflammatory effects of antioxidants,little is known about the underlying molecularmechanisms.

One potential mechanism is the effect of antioxidants on the production of immunoregulatory molecules such as cytokines. Cytokinesare induced in response to brain injury and can mediate and inhibitcellular injury and repair. Many clinical studies report increasedcytokine expression in the CSF or in postmortem brain tissue ofpatients that have suffered stroke or brain injury. Several linesof evidence indicate that proinflammatory cytokines such as interleukin-1(IL-1), tumor necrosis factor (TNF), and transforming growth factor- $beta$ increase with aging (Lynch, 1998; Knoblach et al., 1999).

Several studies have examined antioxidants and their effects in aged animals and humans. Diets enriched in fruits and vegetablesthat have a high antioxidant capacity as measured by oxygen radicalabsorbance capacity (ORAC) (Cao et al., 1997) fed to rats forperiods as short as 2 weeks to 2 months starting at 18 monthsof age can reverse the age-related onset of some behavioral andneurochemical deficits (Gould and Bickford, 1997; Joseph et al.,1999; Bickford et al., 2000). Much of the evidence supportingthe beneficial role of fruits and vegetables to health comes fromepidemiological literature. The traditional common diet of theMediterranean region, a diet high in fruits and vegetables, isassociated with a significant (17%) reduction in overall mortalityin the elderly from these regions (Willet et al., 1995). Recentstudies with vitamin E indicate that high doses slow the progressionof certain aspects of Alzheimer's disease (Sano et al., 1997).The nature of the protective effects of specific nutrients foundin fruits and vegetables, such as $beta$ -carotene, vitamin C, and vitaminE, however, is unknown. A single factor is not likely to be theonly effective agent in these studies. With few exceptions, asingle nutrient is not packaged into a single food, and it ispossible that combinations of nutrients have greater protectiveeffects than each nutrientalone.

The present study focused on a well characterized model system to examine the effects of dietary alterations in aged rats.The cerebellar noradrenergic system shows age-related changesin neurophysiology, and these changes might underlie age-relateddeficits in motor learning. The noradrenergic input to cerebellarPurkinje neurons inhibits spontaneous discharge but appears toaugment the "signal to noise" ratio for both excitatory and inhibitoryneurotransmission, and thus has been characterized previouslyas a "modulatory" input (Freedman et al., 1976). The modulatoryeffect of norepinephrine is blunted in aged rats (Bickford, 1993;Gould and Bickford, 1997). In addition, cerebellar norepinephrineis necessary for motor learning. Depletion of cerebellar norepinephrineor blockade of $beta$ -adrenergic receptors impairs performance on arunway task where rats must learn to walk on varying patternsof pegs that protrude from the runway walls (Bickford et al.,1992; Heron et al., 1996). Impaired performance in aged rats inthis task is correlated with the loss of $beta$ -adrenergic receptorfunction (Bickford et al., 1992; Bickford, 1993).

The present study examined the relationship of the effects of diets designed to improve cerebellar $beta$ -adrenergic receptor functionto the in vitro antioxidant activity of fruits and vegetables,whether anti-inflammatory mechanisms mediate the effects of adiet high in fruits and vegetables, and whether proinflammatorycytokines are involved in mediating theseeffects.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals. Male Fischer 344 rats (National Institute on Aging contract colony; Harlan Sprague Dawley, Indianapolis, IN) (n =76; 4 and 18 months of age) were used. The rats were housed inpairs, maintained in environmentally controlled chambers on a12 hr light/dark cycle at 21 ± 1°C, and provided food and waterad libitum.

ORAC assay. The in vitro antioxidant capacity of an aqueous extract of the dietary supplements was measured using an ORACassay (Cao et al., 1993, 1995). Freeze-dried samples were addedto distilled water (2:1), sonicated, and then centrifuged at 10,000× g for 10 min. The supernatant was used for subsequent analysiswith dilutions as needed. The reaction mixture was 1.78 ml of0.75 mmol/l sodium phosphate buffer (PB), pH 7.0, 0.02 ml of $beta$ -phycoerythrin(1.7 × 10⁸ mol/l in PB; Sigma-Aldrich, St. Louis, MO), 0.2 ml of 2,2'-azobis(2- amidinopropane) hydrochloride solution (40 mmol/l in PB),and 0.02 ml of sample. The reaction was run at 37°C, and fluorescencewas determined at 10 min intervals on a scanning fluorescent spectrophotometer(Acufluor) at excitation and emission wavelengths of 540 and 575nM, respectively. All samples were compared with a standard reactionmixture of 1 µM Trolox (final concentration) (obtained from Sigma-Aldrich).

Diet preparation and feeding regimens. NIH-31 (TD 00365; Harlan Teklab, Madison, WI) rodent diet was supplemented with 0.33%w/w dry spirulina (Earthrise Co., Petaluma, CA), freeze-driedSpy apples (including skin), or freeze-dried cucumber (Van DrunenFarms, Momence, IL), approximating a 5 mg/d dry weight dose ofthe supplements. Control diet and the supplements were combinedusing a Waring (Torrington, CT) Blendor and delivered in powderform to the animals. Animals were allowed to feed ad libitum for14 d and were then killed; brain areas were dissected and flashfrozen in liquid nitrogen. The ORACs, determined as 1 µM Troloxequivalents for the diets, were 0.05 (cucumber), 1.1 (apple),and 320(spirulina).

For experiment 1, the rats were fed supplements by oral gavage with 5 mg dry weight of either apple (including skin) or spirulinain 0.5 ml of water. Controls received 0.5 ml of water only. Invivo electrophysiologic measurements under urethane anesthesiawere performed before collecting the cerebellum for cytokine measurements.For experiment 2, instead of oral gavage, the apple and spirulinawere added to the chow. Cytokine levels were measured. For experiment3, rats (young and aged) were fed the diets either ad libitumor by oral gavage (0.5 ml of water) and studied electrophysiologically.For experiment 4, rats were fed a chow diet supplemented withcucumber or a control diet and examined using electrophysiologictechniques or used for cytokinemeasurements.

RNA isolation and RNase protection assay. The animals were decapitated, the brains were removed, the brain regions were dissected,and tissues were frozen in liquid nitrogen and stored at $-$ 80°Cuntil total RNA was extracted (Gemma et al., 2000). Total RNAfrom homogenized tissues was extracted using a Qiagen (Valencia,CA) Rneasy minikit according to the manufacturer's instructions.Total RNA (20 µg) from each sample was hybridized with antisenseradiolabeled probes, after which free probe and remaining single-strandedRNA were digested with RNase A/T1. Double-stranded RNase-protectedfragments were resolved on 5% denaturing polyacrylamide gels.The probe template used was purchased from PharMingen (San Diego,CA) and included rat-specific sequences for IL-1 $alpha$ , IL-1 $beta$ , IL-2,IL-3, IL-4, IL-5, IL-6, IL-10, TNF $alpha$ , TNF $beta$ , and interferon- $gamma$ (IFN $gamma$ ).A positive control transcript was made using a probe specificfor the ribosomal protein L32, a housekeeping gene, to calculatethe specific activity and obtain a sufficient excess of the L32probe. The L32 probe was then added to the probe template beforethe hybridization reaction started. Yeast transfer RNA and ratmRNA were used as negative and positive controls, respectively.Dried gels were placed on a phosphorimager screen for 16-20 hr.The phosphorimaging screen was subsequently scanned with a phosphorimager(Molecular Image System GS-363; Bio-Rad, Hercules, CA). The imageswere processed using Molecular Analyst software (Bio-Rad). Theintensity of a band in the computer-generated image was directlyproportional to the amount of radioactivity within the band. Theoptical density (OD) values obtained from each band were normalizedagainst the OD obtained from the L32 band in that sample by thefollowing equation: [(OD of the sample band/OD of the L32 band)× 100].

Electrophysiology. Rats were anesthetized with urethane (0.75-1.25 gm/kg), intubated, and allowed to breathe spontaneously.Corneal reflex and toe pinch were used to monitor the anestheticlevel to establish adequate anesthesia. A heating pad was usedto maintain body temperature at 37°C. Animals were placed in astereotaxic frame, and the skin and muscle over the posteriorvermis was removed. The cistern was drained, and the skull anddura over the vermis were removed. The brain was covered withsolution of 2% agar in saline. Extracellular recordings were madefrom Purkinje cells in lobules VI and VII of the cerebellar vermisas identified by anatomic location and the characteristic complexspiking of Purkinje cells (Eccles et al., 1967).

Neuronal signals were amplified, filtered ( $-$ 3 dB at 0.3 and 5 kHz), and displayed on a storage oscilloscope. Action potentialswere isolated using a window discriminator, and the firing outputwas displayed using a strip chart recorder. Single units had asignal to noise ratio of at least 2:1. Multibarrel glass micropipetteswere used for single-cell recording and local drug applicationvia microiontophoresis. The resistance of the recording electrodeswas 1.5-3.3 M $Omega$ . In the multibarrel glass micropipettes, two barrelswere filled with 3 M NaCl and the other two barrels were filledwith GABA (0.25 M, pH 4.0-4.5) and with the $beta$ -adrenergic agonistisoproterenol (ISO; 0.25 M, pH 4.0-4.5), respectively. A constant-currentsource provided ejection and retention currents for the drug barrelsand passed an equal current of opposite polarity through the balancebarrel to neutralize the tip potential. Uniform pulses of drugwere applied at regularintervals.

Current was adjusted until GABA application produced a 10-30% inhibition of Purkinje cell firing. Four applications of GABAwere given with a stable baseline response before ISO was coadministered.The level of ISO was adjusted until either a $>=$ 10% change in GABA-inducedPurkinje cell inhibition was observed for four applications ofGABA or until the baseline Purkinje cell firing rate was altered.After ISO was turned off, GABA application continued until itcould be determined whether the pre-ISO level of GABAergic inhibitionreturned. Only Purkinje cells in which the post-ISO level of GABAergicinhibition matched the pre-ISO level of GABAergic inhibition wereanalyzed. Drug-induced responses were quantified by computer.The Datawave (Longmont, CO) system was used to acquire and quantifydrugresponses.

Determination of malondialdehyde by HPLC with spectrofluorometric detection. Analysis of the lipid peroxidation by product,malondialdehyde (MDA), by HPLC, with spectrofluorometric detection,was used to overcome the limitations of the thiobarbituric acid(TBA) reaction by chromatographically separating the MDA-TBA conjugatefrom contaminating fluors that arise during the TBA reaction.In a microassay adaptation of the TBA reaction, small aliquots(10-50 µl) of tissue extracts are combined in a 1.5 ml microcentrifugetube with 250 µl of 0.5 M phosphoric acid, 250 µl of 42 mmol/lTBA in acetic acid, and 50 µl of 500 ppm butylated hydroxytoluene.Samples are then placed into a 100°C heating block for 45 min.A 150 µl postreaction aliquot was neutralized with 1N NaOH inMeOH and immediately injected onto the column for chromatographicanalysis. MDA peak identification and quantification were determinedby comparison with a standard curve of MDA-TBA adduct generatedby acid hydrolysis of working standards of 1,1,3,3-tetraethoxypropane.

Statistical analyses. One-way ANOVA was used to analyze the OD values. Fisher's exact test was used for the electrophysiologicdata, because it was nonparametric. A p value of <0.05 was consideredto be statisticallysignificant.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Electrophysiologic recordings were performed to determine whether these diets produced functional changes in the cerebellum,previously observed with other antioxidant-enriched chow-fed diets(blueberry, spinach, strawberry, and vitamin E). There were nosignificant differences between chow-fed rats or gavage-fed rats(young gavage, 57 ± 3, n = 7; young chow, 59 ± 3, n = 7; old gavage,19 ± 2, n = 5; old chow, 21 ± 2, n = 6); therefore, these dietarystrategies were considered equivalent for the electrophysiologicstudies. $beta$ -adrenergic receptor function was examined by testingthe ability of iontophoretically applied ISO to increase the inhibitoryresponse to iontophoretically applied GABA while recording thespontaneous firing rate of Purkinje neurons using extracellularmultibarrel electrodes. There was an age-induced decrease in $beta$ -adrenergicfunction in control aged animals. Figure 1A shows a typical responseto GABA in an aged rat where a 20% inhibition of spontaneous firingrate is observed. Figure 1B shows that when ISO is applied concurrentlywith GABA, the increase in GABAergic inhibition typically observedin a Purkinje cell from a young rat does not occur. Conversely,in an aged rat fed spirulina, ISO augments the GABAergic inhibitionfrom a baseline of 18% (Fig. 1D) to 91% (Fig. 1E). Figure 2 summarizesthe results from all rats. In young rats (n = 14), >75% of recordedPurkinje neurons demonstrated an ISO-mediated increase in GABAergicinhibition. In the control 18-month-old rats (n = 11), only 40%of neurons responded to ISO with an increase in GABAergic inhibition(p < 0.05; Fisher's exact test). When rats were fed spirulina(n = 6; 5 mg in 0.5 ml by oral gavage daily), >75% of the Purkinjeneurons had an ISO-mediated increase in GABAergic inhibition,a statistically significant reversal of the age-related impairmentof $beta$ -adrenergic receptor function. Rats fed apple (n = 6; 5 mgin 0.5 ml by oral gavage daily) showed intermediate improvement;they were not statistically different from the aged controls,yet they were also not statistically different from the youngrats or the spirulina-treated group. When rats were fed a cucumberdiet for 14 d (n = 6; 0.33% freeze-dried powder in NIH-31 diet)there was no improvement in the ISO-mediated GABA inhibition ofthe cerebellar Purkinje neuron firing rate.

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Figure 1. Peri-event time histograms showing the response to iontophoretically applied GABA onto single cerebellar Purkinje neurons from an aged rat on the control diet (left) or an aged rat fed a spirulina-enriched diet for 2 weeks (right). The top panels (A, D) show baseline responses to a 5 sec application of GABA. The middle panels (B, E) show responses to GABA during concurrent application of ISO. The bottom panels (C, F) represent recovery after termination of the ISO. Histograms represent averages of four drug responses. The x-axis represents time in seconds and the y-axis represents action potentials per 0.5 sec time bin.

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Figure 2. The ability of ISO to augment GABAergic inhibition of cerebellar Purkinje neurons was examined in young rats (n = 7 rats, 42 neurons for gavage; n = 7 rats, 57 neurons for control diet) and aged rats fed apple (n = 6 rats, 38 neurons, fed via oral gavage), spirulina (n = 6 rats, 38 neurons, fed via oral gavage), vehicle (n = 5 rats, 40 neurons, fed via gavage; n = 6 rats, 33 neurons, normal diet), or cucumber (n = 6 rats, 35 neurons, fed via diet supplement) for 2 weeks. There were no differences between young or aged controls on the diet versus gavage treatment; therefore the samples were pooled. The ability of ISO to augment GABAergic inhibition of Purkinje cell spontaneous firing was the dependent measure. The spirulina diet significantly reversed the age-induced decrease in the $beta$ -adrenergic receptor response (p < 0.05; Fisher's exact test). The apple diet had an intermediate effect (not significantly different from either control or spirulina), and the cucumber diet did not produce any change.

To evaluate neuroinflammatory processes that occur during normal aging, we used the RNase protection assay (RPA) to determinethe mRNA expression of proinflammatory cytokines. A representativeexample of a gel taken from the phosphorimaging system is depictedin Figure 3. In this particular RPA, total cerebellar RNA from20-month-old and 4-month-old rats was assayed. In the young rats,there is very low expression of mRNA for proinflammatory cytokines.In contrast, bands corresponding to TNF $beta$ , IL-6, IL-10, TNF $alpha$ , andIFN $gamma$ are observed in the aged rat samples. Because TNF $alpha$ and TNF $beta$ were the major bands observed in the aged rats, they were analyzedquantitatively. The expression of TNF $alpha$ and TNF $beta$ mRNA was age-related(Fig. 4). The cerebellum from 20-month-old rats (n = 6) showedsignificantly higher expression of mRNA for both cytokines whencompared with those obtained from 4-month-old animals [n = 6;TNF $alpha$ , F = 49.3 (one-way ANOVA), p < 0.001; TNF $beta$ , F = 152, p <0.001].

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Figure 3. Representative image of a 5% denaturing polyacrylamide gel obtained by a phosphorimager on which double-stranded RNase-protected fragments were resolved. Total mRNA was extracted from the cerebellum of rats aged 4 and 20 months. The template consisted of radiolabeled antisense RNA probes for IL-1 $alpha$ (protected probe size, 403 nt), IL-1 $beta$ (361 nt), TNF $beta$ (322 nt), IL-3 (286 nt), IL-4 (256 nt), IL-5 (226 nt), IL-6 (202 nt), IL-10 (181 nt), TNF $alpha$ (160 nt), IL-2 (142 nt), and IFN $gamma$ (129 nt). Tem, Template.

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Figure 4. Age-related mRNA expression of TNF $alpha$ and TNF $beta$ in cerebellar tissue of male Fischer 344 rats. TNF $alpha$ and TNF $beta$ mRNA expression was significantly increased in cerebellar tissues dissected from aged rats (20 months; n = 6) compared with young rats (4 months; n = 6) (one-way ANOVA: TNF $alpha$ , F = 49, p < 0.0001; TNF $beta$ , F = 152, p < 0.0001). An internal standard control gene, ribosomal protein L32, was included in the template, and the OD of each band for cytokine mRNA was normalized relative to the OD of the L32 band by the following expression: (OD of the cytokine mRNA band/OD of the L32) × 100.

We subsequently examined whether the expression of proinflammatory cytokines was modulated by diets enriched with foods highin antioxidant activity using spirulina and apple diets. Ratswere also fed a cucumber-enriched diet, a food with low ORAC.Cytokine measurements were identical between diet-fed rats orgavage-fed rats; however, there was less variability, so the cytokinemeasurement data from chow-fed rats are presented. The cerebellaobtained from the aged animals fed the spirulina-supplementeddiet (n = 8) and apple (n = 7) showed decreased expression ofTNF $alpha$ or TNF $beta$ mRNA [spirulina: TNF $alpha$ , F = 13 (one-way ANOVA), p< 0.0004; TNF $beta$ , F = 22.6, p < 0.0006; apple: TNF $alpha$ , F = 11.5, p< 0.007; TNF $beta$ , F = 19, p < 0.001] (Fig. 5). In contrast, in animalsfed cucumber (n = 6), the expression of mRNA was not differentfrom that in animals maintained on the control diet.

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Figure 5. The age-related increase in TNF $alpha$ and TNF $beta$ mRNA expression in rat cerebellar tissue is prevented by diets rich in antioxidants. The TNF $alpha$ and TNF $beta$ mRNA expression was significantly decreased in cerebellar tissue obtained from aged rats (18 months) fed for 2 weeks with either spirulina (n = 6) (0.33% w/w dry; spirulina vs aged controls; p < 0.005 and p < 0.001 for TNF $alpha$ and TNF $beta$ , respectively) or apple (n = 6) (5 mg/d dry weight; apple vs aged controls; p < 0.005 and p < 0.001 for TNF $alpha$ and TNF $beta$ , respectively) compared with aged rats fed on control diet. The cucumber diet did not produce any significant change in TNF $alpha$ and TNF $beta$ .

To evaluate the effects of the apple, spirulina, and cucumber diets on an index of oxidative stress, we measured the levelsof MDA in the cerebellum. MDA levels were significantly higherin the aged control rats (Fig. 6). The levels of MDA were significantlylower in aged rats fed apple- and spirulina-enriched diets comparedwith aged controls. The cucumber diet did not decrease MDA levels.

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Figure 6. MDA values are increased in control aged rats (n = 6) compared with young rats (n = 6), and apple (n = 6) and spirulina (n = 6) diets bring those values back toward those observed in young rats (p < 0.01; one-way ANOVA). Lipid peroxidation by MDA was measured by a TBA reaction where the MDA-TBA adduct end-product was chromatographically separated. A single MDA-TBA peak is detected by spectrophotometry with absorbance at 532 nm and emission at 553 nm. Values are expressed in picomoles of MDA per milligram wet weight of tissue.

  DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Aged Fischer 344 rats fed either spirulina- or apple-enriched diets for 14 d have improved $beta$ -adrenergic receptor function,downregulation of proinflammatory cytokines, and decreased MDAin the cerebellum. There was no improvement, however, in ratsfed a diet supplemented with equivalent amounts of cucumber, afood with a lowORAC.

It is widely thought that diet-derived antioxidants have a role in the prevention of human disease. Diets rich in fruits,grains, and vegetables are protective against several human diseases,especially cardiovascular disease and some types of cancer (Halliwelland Gutteridge, 1999). We have demonstrated previously that vitaminE and/or extracts of strawberries, blueberries, and spinach fedto rats for 2 weeks to 2 months starting at 18 months of age canreverse the age-related onset of some behavioral and neurochemicaldeficits (Gould et al., 1998; Joseph et al., 1999; Bickford etal., 2000). It is unlikely, however, that a single factor is theeffective agent; there are many constituents in food that mightexert additional antioxidant effects or protect by completelydifferent mechanisms. It is important to take into account thatsome compounds that have limited direct antioxidant activity mightexert antioxidant action in vivo by upregulating endogenous antioxidantfactors.

In the present study, mRNA expression of TNF $alpha$ and TNF $beta$ in the cerebellum of aged rats was dramatically enhanced when comparedwith the cerebellum of young rats, suggesting that inflammatorymechanisms are involved in normal aging processes and that centralmechanisms for the production of proinflammatory cytokines areage dependent. The increase in mRNA expression of TNF $alpha$ and TNF $beta$ in the cerebellum of old rats completely reversed when aged animalswere fed apple- or spirulina-supplemented diets for 2 weeks, butnot when they were fed cucumber, suggesting that at least someof the beneficial effects of these enriched diets on physiologicparameters, such as $beta$ -adrenergic receptor function, might be exertedthrough the downregulation of inflammatorymediators.

The observation that these effects are rapid is consistent with previous literature indicating that these antioxidants, suchas the free radical scavenging spin-trap agent, phenyl-butyl-tert-nitroneand vitamin E, can have beneficial effects in this short periodof time (Carney et al., 1991; Gould et al., 1998). Thus, the actionof these foods might be to downregulate ongoing oxidative stressand/or inflammatory processes, allowing for the recovery of functionof cellular homeostasis. There is a rapid reversal of oxidativedamage to protein and membranes (Carney et al., 1991),which might underlie the functional recovery observed. The invitro ORACs of spirulina, apple, and cucumber are different. Spirulinahas an ORAC activity that is 300-fold higher than that measuredin apples. Apple, spirulina, and cucumber were given to the animalsin the same milligram quantities so that the relative ORAC presentin each diet was different. The ORAC determination was performedon the aqueous extract; therefore it could be an underestimateof the total ORAC for the sample, because some of the phytochemicalswould not be extracted into an aqueous extract. Nonetheless, thereversal of the electrophysiologic alterations in $beta$ -adrenergicreceptor function is consistent with an ORAC dose relationship,because the apple data were intermediate between the results observedwith spirulina and cucumber. The spirulina produced results similarto those reported previously with blueberry and spinach, foodswith ORAC equivalents of ~3 (Joseph et al., 1999). In previousstudies, an ~60 times higher amount of the food was given, sothe studies are not directly comparable, yet this also indicatesa dose relationship of the antioxidant amounts on the observedchanges in $beta$ -adrenergic receptor function. The ORAC dose relationshipis less clear when changes in proinflammatory cytokines are examined.In aged rats fed either apple or spirulina, the overproductionof TNF was completely reversed, whereas in aged rats fed cucumber,which is low in ORAC, TNF levels were not affected. The in vitroORAC of apples is lower than that of spirulina, but both appleand spirulina completely reversed the increase in the mRNA forTNF $alpha$ and TNF $beta$ , suggesting that the phytochemicals in apple weresufficient to produce this downregulation of cytokines. Spirulinahad no other detectable effects, suggesting that the effect wasmaximal and that there was a floor so that no additional changecould be observed. A similar profile was observed for the MDAlevels in the cerebellum. The apple diet, however, had an intermediateeffect on the electrophysiologic measures of $beta$ -adrenergic receptorfunction. One explanation for this divergence is that the antioxidantand/or anti-inflammatory dose requirement for observing a differencein the $beta$ -adrenergic receptor signal transduction cascade is differentfrom what is needed to observe a change in proinflammatory cytokinesand MDA. Alternately, ORAC is a crude in vitro measure, and thereare multiple components in both apple and spirulina that resultin the observed effects on cytokines, MDA, and the electrophysiologicmeasures. It is possible that the differences observed betweenapple and spirulina relate to these different phytochemical profiles.In addition, these different phytochemicals might have varyingabilities to cross the blood-brain barrier and thus produce effectsin the CNS. Additional research is required to examine subcomponentsof these foods and dose responses to these components to examinethis question in moredetail.

Spirulina is a microalga, rich in protein and other essential nutrients. Spirulina contains phycobiliprotein (phycocyaninand allophycocyanin), phenolic acid, tocopherols, and $beta$ -carotene.Although all of these components exhibit high antioxidant properties,the antioxidant activity of spirulina, when evaluated againstoxidation of methyl linoleate in a hydrophobic system, is primarilyrelated to the biliprotein phycocyanin component (Hirata et al.,2000). The contribution of phycocyanin to the antioxidant effectsof spirulina has been investigated in other systems. An increasein the antioxidant activity of different fractions of spirulina,obtained during the phycocyanin purification process, is relatedto an increase in phycocyanin content (Pinero Estrada et al.,2001). Other investigators report that when administered orallyto mice at 100 or 200 mg/kg, phycoerythrin inhibits glucose oxidase-inducedinflammation of the paw in a dose-dependent manner (Romay et al.,1998). However, apple contains phenolic, flavonoid, and flavonoid-sugarcompounds, and quercetin is major dietary flavonoid. There aremore phenolics in the skin of apples than in the flesh, and quercetinglycosides are found only in the skins. The antioxidant effectsof apple extracts with skin and apple extracts without skin havebeen tested on the proliferation of several kinds of cancer celllines. The whole-apple extract either with skin or without skininhibits the growth of colon and cancer cells in vitro in a dose-dependentmanner, suggesting that the combination of phytochemicals includingphenolic acid and flavonoids present in the skin and flesh areresponsible for the antioxidant effects of apple (Eberhardt etal., 2000). These observations suggest that not only one componentbut perhaps a combination of nutrients in foods have greater protectiveeffects than each nutrientalone.

There is a possible link between the $beta$ -adrenergic receptor and proinflammatory cytokines. Several studies report anti-inflammatoryproperties of $beta$ -adrenergic receptors on immune cells under stressconditions (Haskoó et al., 1998; Zhang et al., 1999). In addition,a large body of evidence suggests that $beta$ -adrenergic receptor agonistsdecrease TNF release through a mechanism mediated by cAMP (Zhanget al., 1999). Because there is a downregulation of $beta$ -adrenergicreceptor function in Purkinje neurons of the aged cerebellum,which translates at least as far as induction of cAMP (Gould andBickford, 1997), it is possible that a blunted $beta$ -adrenergic responseof immune cells is related to the observed increase in proinflammatorycytokines. Additional studies are needed to determine whetherthis mechanism acts in the cerebellum of agedrats.

In conclusion, the beneficial effects of diets rich in fruits and vegetables are related, at least in part, to the ORAC ofthe compounds present in the diet. In addition, the nutrientsinfluence the appearance of proinflammatory cytokines in the cerebellumof aged rats, inducing an anti-inflammatory response in the agedrat cerebellum. This raises the possibility that some of the effectsof diets enriched with foods with high antioxidant activity arerelated to an interaction with the proinflammatorycytokines.

  FOOTNOTES

Received Dec. 5, 2001; revised March 25, 2002; accepted April 4, 2002.

This work was supported by the Veterans Affairs Medical Research Service and United States Public Health Service Grants AG04418andAG00728.

Correspondence should be addressed to Dr. Paula C. Bickford, Center for Aging and Brain Repair, Department of Neurosurgery,MDC-78, University of South Florida, College of Medicine, 12901Bruce B. Downs Boulevard, Tampa, FL 33612. E-mail: pbickfor{at}hsc.usf.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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