Increased Susceptibility to Ischemic Brain Damage in Transgenic Mice Overexpressing the Amyloid Precursor Protein

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Volume 17, Number 20, Issue of October 15, 1997 pp. 7655-7661
Copyright ©1997 Society for Neuroscience

Increased Susceptibility to Ischemic Brain Damage in Transgenic Mice Overexpressing the Amyloid Precursor Protein

Fangyi Zhang¹, Chris Eckman², Steven Younkin², Karen K. Hsiao¹, and Costantino Iadecola¹
¹ Department of Neurology, University of Minnesota, Minneapolis, Minnesota 55455, and ² Mayo Clinic Jacksonville, Jacksonville, Florida 32224

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

We studied the role of the amyloid precursor protein (APP) in ischemic brain damage using transgenic mice overexpressing APP.The middle cerebral artery (MCA) was occluded in FVB/N mice expressingAPP₆₉₅.SWE (Swedish mutation) and in nontransgenic littermates.Infarct volume (cubic millimeters) was assessed 24 hr later inthionin-stained brain sections. The infarct produced by MCA occlusionwas enlarged in the transgenics (+32 ± 6%; n = 12; p < 0.05; ttest). Measurement of APP by ELISA revealed that, although relativelyhigh levels of A $beta$ were present in the brain of the transgenics(A $beta$ _1-40 = 80 ± 19 pmol/g; n = 6), there were no differencesbetween ischemic and nonischemic hemispheres (p > 0.05). The reductionin cerebral blood flow produced by MCA occlusion at the peripheryof the ischemic territory was more pronounced in APP transgenics( $-$ 42 ± 8%; n = 9) than in controls ( $-$ 20 ± 8%; n = 9). Furthermore,the vasodilatation produced by neocortical application of theendothelium-dependent vasodilator acetylcholine (10 µM) was reducedby 82 ± 5% (n = 8; p < 0.05) in APP transgenics. The data demonstratethat APP overexpression increases the susceptibility of the brainto ischemic injury. The effect is likely to involve the A $beta$ -induceddisturbance in endothelium-dependent vascular reactivity thatleads to more severe ischemia in regions at risk for infarction.The cerebral vascular actions of peptides deriving from APP metabolismmay play a role in the pathogenic effects of APP.
Key words: middle cerebral artery; Alzheimer's disease; cerebral ischemia; stroke; cerebral blood flow; transgenic mice

INTRODUCTION

There is substantial evidence that the amyloid precursor protein (APP), a constitutively expressed transmembrane glycoprotein,is involved in the pathogenesis of Alzheimer's dementia (Priceand Sisodia, 1994; Selkoe et al., 1996; Mattson et al., 1997).APP is present in different isoforms derived from a single geneby alternative splicing (Lendon et al., 1997). A 39-42 amino acidfragment of APP, A $beta$ , is present in amyloid plaques in the brainof patients with Alzheimer's disease and Down's syndrome and innormal brain aging (Lendon et al., 1997). Both in vitro and invivo evidence suggest that A $beta$ is cytotoxic, an effect that maydepend on the state of aggregation of A $beta$ (Mattson et al., 1993a).The mechanisms of the neurotoxicity of A $beta$ are thought to includeperturbation of ionic homeostasis and free radical production(Mattson et al., 1993a; Fraser et al., 1997).

It has been proposed that APP and A $beta$ may also participate in ischemic brain damage. Although APP expression is increased inthe postischemic brain (Abe et al., 1991a,b; Stephenson et al.,1992; Wakita et al., 1992; Kalaria et al., 1993; Banati et al.,1995), cerebral ischemia may facilitate cleavage of APP into thetoxic A $beta$ fragment (Saido et al., 1994; Yokota et al., 1996). Theseobservations raise the possibility that ischemia leads to accumulationof A $beta$ , which, in turn, could contribute to ischemic brain damage.On the other hand, there is also evidence that APP may protectvulnerable neurons from global cerebral ischemia and attenuatesneurotoxicity in neuronal cultures (Mattson et al., 1993a; Smithet al., 1994). Therefore, the role of APP in ischemic brain damagehas not been elucidated.

The study of the role of APP in cerebral ischemic injury could benefit from recently developed transgenic mice overexpressingdifferent isoforms of APP (e.g., Games et al., 1995; Higgins etal., 1995; Hsiao et al., 1995, 1996). In the present study, therefore,we used APP transgenics to determine whether APP overexpressionexacerbates ischemic brain damage and, if so, to establish whetherthe effect is related to ischemia-induced accumulation of A $beta$ .We found that occlusion of the middle cerebral artery (MCA) inAPP mice produces larger cerebral infarcts than in nontransgeniclittermates. The effect is not associated with increased A $beta$ levelscompared with the contralateral nonischemic brain. In addition,the reduction in cerebral blood flow (CBF) produced by MCA occlusionis more severe in APP transgenics than in controls, although theCBF increase produced by neocortical application of acetylcholine(ACh) is attenuated in APP transgenics. The data indicate thatAPP overexpression is deleterious to the postischemic brain. Theeffect may derive from the neurotoxicity of A $beta$ and from A $beta$ -inducedloss of vascular reactivity resulting in more severe ischemia.Therefore, vascular factors have to be taken into account whenexamining the pathogenic effects of APP and its metabolites onthe CNS.

MATERIALS AND METHODS
Animals The APP variant known as the Swedish mutation (APP₆₉₅.SWE) was overexpressed in FVB/N mice using a prion protein cosmid vector(Hsiao et al., 1995). APP mice develop behavioral abnormalitiesassociated with astrogliosis and decreased glucose use in selectedtelencephalic regions (Hsiao et al., 1995). The transgenics donot exhibit histological evidence of $beta$ -amyloid deposits in brainor blood vessels (Hsiao et al., 1995). Mice were studied at age3-4 months (body weight, 25-30 gm). All mice were genotyped todetermine the presence of the transgene. Nontransgenic littermateswere used as controls.
Induction of focal cerebral ischemia Focal cerebral ischemia was produced by occlusion of the MCA. Techniques for MCA occlusion in mice were similar to those describedpreviously for the rat (Zhang and Iadecola, 1992). Mice were anesthetizedwith 2% halothane in 100% oxygen. Body temperature was maintainedat 37 ± 0.5°C by a thermostatically controlled infrared lamp.A 2 mm hole was drilled in the inferior portion of the temporalbone to expose the left MCA. The MCA was elevated and cauterizeddistal to the origin of the lenticulostriate branches (Zhang andIadecola, 1992). Wounds were sutured, and mice were allowed torecover and returned to their cages. Rectal temperature was controlleduntil mice regained full consciousness. The animals were killed24 hr after MCA occlusion for measurement of infarct size andfor A $beta$ determination (see below).
Determination of infarct volume Mice were killed for determination of infarct volume 1 d after MCA occlusion. Brains were removed and frozen in cooled isopentane( $-$ 30°C). Coronal forebrain sections (thickness 30 µm) were seriallycut in a cryostat, collected at 150 µm intervals, and stainedwith thionin for determination of infarct volume by an image analyzer(M1, Imaging Research Inc.) (Zhang and Iadecola, 1992). To factorout the contribution of ischemic swelling to the total volumeof the lesion, infarct volume in cerebral cortex was correctedfor swelling as described previously (Zhang and Iadecola, 1994;Iadecola et al., 1995). The correction method is based on thedetermination of ischemic swelling by comparing the volume ofischemic and nonischemic hemispheres (Lin et al., 1993).
Determination of A $beta$ APP transgenics were killed 24 hr after MCA occlusion. The infarcted cortex and the contralateral intact cortex were dissectedout and frozen in liquid nitrogen and stored at $-$ 80°C until analysis.Techniques for A $beta$ measurement have been described in detail previously(Suzuki et al., 1994; Gravina et al., 1995) and are summarized.Approximately 0.2 gm of tissue was homogenized in 1 ml of 70%formic acid and centrifuged at >100,000 × g for 1 hr. The formicacid extract was removed, and a small aliquot was diluted 50 timesin 1 M Tris, pH 8.0. This sample was then further diluted 2.4times in buffer EC (0.02 M sodium phosphate, pH 7.0, 0.2 mM EDTA,0.4 M NaCl, 0.2% bovine serum albumin, 0.05% 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonicacid, 0.4% Block-Ace, and 0.05% sodium azide), and 100 µl of thissolution was analyzed directly using either the BNT77/BA27 orBNT77/BC05 sandwich ELISA system (Suzuki et al., 1994; Gravinaet al., 1995). A $beta$ values were obtained by comparing the absorbanceobtained from duplicate samples to standard curves of either A $beta$ _1-40(BNT77/BA27) or A $beta$ _1-42 (BNT77/BC05) with a standard curve(Bachem). Absorbance values were corrected for dilution and initialwet weight.
Determination of cerebral blood flow Techniques used for studying the cerebral circulation in mice were similar to those described previously (Dalkara et al.,1995; Sobey and Faraci, 1997). Mice were anesthetized with halothane(maintenance 1%), and the femoral artery and trachea were cannulated.Mice were artificially ventilated with an oxygen-nitrogen mixtureby a mechanical ventilator (SAR-830; CWI Inc., Ardmore, PA). Theinspiration time was set at 0.1 sec, the respiratory rate at 120/min,and the inspiratory flow at ~250 ml/min. The oxygen concentrationin the mixture was adjusted to obtain an arterial P_O₂ of 150-170mmHg. End-tidal CO₂ was continuously monitored using a CO₂ analyzer(Capstar-100, CWI Inc.). The sample flow rate of the CO₂ analyzerwas set at 10 cc/min. Great care was taken to accurately monitorarterial P_CO₂ and P_O₂, critical variables for studies of the cerebralcirculation (Heistad and Kontos, 1983). In preliminary studies(n = 10), we established the relationship between end-tidal CO₂and arterial P_CO₂, measured by a blood gas analyzer (model 178;CIBA-Corning, Medfield, MA). The relationship was linear betweenP_CO₂ values of 31 and 67 mmHg (r² = 0.92; p < 0.001; n = 28). Throughout the experiment, end-tidalCO₂ was maintained at 2.6-2.7%, which corresponds to a P_CO₂ of33-35 mmHg. The P_O₂ of the mice was 166 ± 11, and the pH was 7.40± 0.04.

MCA occlusion. For monitoring of the changes in CBF produced by MCA occlusion, two laser Doppler flow probes (Vasamedic, St.Paul, MN) were placed through burr holes placed in the center(3.5 mm lateral to the midline and 1 mm caudal to bregma) andthe periphery (1.5 mm lateral to the midline and 1.7 mm rostralto lambda) of the ischemic territory (Chan et al., 1993). Afterplacement of the probes, the MCA was occluded, and CBF was monitoredfor 60 min. CBF data are expressed as a percentage of the preocclusionvalue.

Cerebrovascular reactivity. Techniques for testing cerebral microvascular reactivity in mice were similar to those describedpreviously in rats (Iadecola, 1992; Iadecola and Zhang, 1996).Mice were anesthetized and instrumented as described above. Acranial window was drilled in the parietal bone to expose theparietal cortex. The dura was removed, and the site was superfusedwith Ringer's solution (37°C; pH 7.3-7.4). CBF was continuouslymonitored at the site of superfusion with a laser Doppler probe.After stabilization of arterial pressure and blood gases, ACh(10 µM; Sigma, St. Louis, MO) was superfused. After the CBF increasereached a steady state (usually 3-5 min), ACh was discontinued,and CBF returned to baseline. The nitric oxide donor S-nitroso-N-acetylpenicillamine(SNAP) (500 µM) was then topically applied, and the changes inCBF were monitored. The concentrations of ACh and SNAP were theEC₅₀ values, as determined by dose-response curves in preliminaryexperiments.
Data analysis Data in text and figures are expressed as mean ± SE. Two-group comparisons were analyzed by the two-tailed t test for independentor paired samples as appropriate. p < 0.05 was considered statisticallysignificant.

RESULTS

Effect of MCA occlusion on infarct size in APP transgenics
In nontransgenic mice (n = 13), MCA occlusion distal to the origin of the lenticulostriate arteries produced infarcts involvingmainly the cerebral cortex (Figs. 1, 2). Size and distributionof the lesion were comparable to those described previously inwild-type mice (e.g., Barone et al., 1993). In APP transgenics(n = 12) the cortical infarcts produced by MCA occlusion werelarger (+32 ± 6%) than those of nontransgenic littermates (Figs.1, 2). The effect persisted after correction for swelling (Fig.1A). The volume of brain swelling was 10.8 ± 1 mm³ in APP transgenics and 10.5 ± 0.6 mm³ in nontransgenic mice (p > 0.05). The area recruited into infarctioninvolved the medial edge of the cortical lesion throughout therostrocaudal extent of the infarct (Figs. 1B, 2).
Fig. 1. Effect of MCA occlusion on cerebral ischemic damage in FVB/N transgenic mice overexpressing APP₆₉₅.SWE. A, MCA occlusion resultedin larger infarcts in APP transgenics than in nontransgenic littermates(p < 0.05, t test), an effect that persists after correction forischemic swelling (corrected). B, Rostrocaudal distribution ofthe ischemic lesion produced by MCA occlusion in APP transgenicsand nontransgenic littermates. The enlargement of the lesion occursboth in the anterior and posterior regions of the infarct (p <0.05).
[View Larger Version of this Image (24K GIF file)]

Fig. 2. Brain sections from representative animals indicating the distribution of the ischemic lesion in nontransgenic mice (Non-Tg)and in FVB/N transgenic mice overexpressing APP₆₉₅.SWE [APP Tg(FVB/N HuAPP₆₉₅.SWE)]. The area recruited into infarctionin the transgenics involves the periphery of the lesion uniformlyat all rostrocaudal levels.
[View Larger Version of this Image (27K GIF file)]

A $beta$ concentration in the postischemic brain
To determine whether cerebral ischemia leads to accumulation of A $beta$ , we measured A $beta$ concentration in the ischemic region ofAPP transgenic mice 24 hr after MCA occlusion (n = 6). In agreementwith previous data (Hsiao et al., 1995), transgene-derived A $beta$ _1-40and A $beta$ _1-42 were present in the brain (Fig. 3). However,the concentration of these peptides did not differ between ischemicand nonischemic hemispheres (p > 0.05, paired t test) (Fig. 3).
Fig. 3. Effect of MCA occlusion on A $beta$ concentration in the ischemic territory in FVB/N transgenic mice overexpressing APP₆₉₅.SWE.A $beta$ was measured 24 hr after MCA occlusion using an ELISA-basedmethod (for details, see Materials and Methods). Transgene-derivedA $beta$ [(1-40), (1-42)] was present in the brain. However, the A $beta$ concentration did not differ between ischemic and nonischemichemispheres (p > 0.05, paired t test). The ratio between the 1-40and 1-42 peptides [(1-42)/(1-40)×100] also did not change.
[View Larger Version of this Image (17K GIF file)]

Effect of MCA occlusion on CBF in APP transgenics and nontransgenic mice
We then sought to determine whether the severity of CBF reduction produced by MCA occlusion was comparable in APP transgenicsand nontransgenic mice. In these experiments, CBF was monitoredin the center and the periphery of the ischemic territory beforeand after MCA occlusion. In the center of the ischemic territory,CBF was reduced by ~80% of the preischemic level, indicating thatthe probe was in the ischemic core, a region of severe ischemiain which brain cells die rapidly. At the periphery of the ischemicregion, flow was reduced by 30-40%, a reduction consistent withprobe placement into the so-called ischemic penumbra, an areaof less severe ischemia surrounding the ischemic core (Hossmann,1994). Before MCA occlusion, resting CBF was 22.6 ± 1.7 perfusionunits in APP transgenics and 24.4 ± 0.9 in nontransgenics (p >0.05). In the ischemic core, the decrease in CBF was virtuallyidentical in transgenic (n = 9) and nontransgenic mice (n = 9)(Fig. 4). However, in the ischemic penumbra the reduction in CBFwas greater in APP mice than in nontransgenic controls (p < 0.05)(Fig. 4). These findings demonstrate that APP mice are subjectedto a greater flow reduction in the ischemic penumbra, a regionat risk for infarction.
Fig. 4. Effect of MCA occlusion on CBF in FVB/N transgenic mice overexpressing APP₆₉₅.SWE and nontransgenic littermates. A, The reductionin CBF in the center of the ischemic core is not different betweentransgenic and nontransgenic mice. B, In the ischemic penumbra,however, CBF is relatively more reduced in APP transgenics (p< 0.05, t test). C, Mean arterial pressure is not different betweenAPP transgenics and nontransgenic littermates.
[View Larger Version of this Image (18K GIF file)]

Cerebrovascular reactivity in APP transgenics
The observation that the reduction in CBF in the penumbra is more marked in APP transgenics suggests that the mechanisms regulatingCBF are impaired in APP transgenics. This possibility is supportedby the observation that in isolated systemic vessels A $beta$ reducesthe relaxation produced by ACh (Thomas et al., 1996). We, therefore,sought to determine whether the reactivity of the cerebral circulationto ACh is impaired in APP transgenics. Resting CBF was 22.9 ±1.8 perfusion units in APP transgenics and 22.1 ± 1.9 in nontransgeniclittermates (p > 0.05). In nontransgenic littermates, topicalapplication of ACh (10 µM) or SNAP (500 µM) increased CBF (Fig.5). However, the increase in CBF produced by ACh was substantiallyattenuated in APP transgenics, whereas the response to SNAP wasnot significantly reduced (Fig. 5). These data suggest that selectedvasodilator responses of the cerebral circulation are impairedin APP transgenics.
Fig. 5. Effect of topical cortical application of ACh or SNAP on the CBF in APP transgenics and nontransgenic littermates. Mice wereanesthetized and artificially ventilated. End-tidal CO₂ was monitoredand maintained between 2.2 and 2.6%, a value that correspondedat a P_CO₂ of 35-38 mmHg (see Materials and Methods). Arterialpressure was 94 ± 8 mmHg in APP transgenics and 84 ± 6 in nontransgenics.The vasodilatation produced by ACh was markedly reduced in APPtransgenics (p < 0.001, t test), whereas the response to SNAPwas not statistically different between transgenic and nontransgenicmice.
[View Larger Version of this Image (15K GIF file)]

DISCUSSION
We sought to study the role of APP in ischemic brain damage. Although global or focal cerebral ischemia induces expressionof APP in neurons and glia (Abe et al., 1991a,b; Stephenson etal., 1992; Wakita et al., 1992; Kalaria et al., 1993; Banati etal., 1995), the biological significance of the APP upregulationremains unclear. Some studies have suggested that APP expressionhas a protective role after cerebral ischemia. For example, APP,administered intracerebroventricularly, reduces hippocampal damageafter global cerebral ischemia in gerbils (Smith et al., 1994),although in vitro APP protects neurons from excitotoxicity (Mattsonet al., 1993b). Other studies, however, have provided evidencethat APP may be detrimental to the ischemic brain. For example,the A $beta$ peptide, a neurotoxic fragment of APP, has been found toaccumulate in vulnerable neurons in the postischemic hippocampus(Yokota et al., 1996). Therefore, it remains to be defined whetherAPP is protective or destructive in cerebral ischemia.

In the present study, we used transgenic mice overexpressing APP₆₅₅.SWE to investigate the effect of APP on ischemic braindamage (Hsiao et al., 1995). These mice develop behavioral abnormalities,gliosis, and reduced glucose use in selected telencephalic regionsby the time they are 8-12 weeks old (Hsiao et al., 1995). APP₆₅₅.SWEmice do not develop amyloid deposition in brain or blood vessels(Hsiao et al., 1995). We found that MCA occlusion in APP transgenicsresults in infarcts that are larger than those of nontransgeniclittermates. These observations indicate that APP overexpressionin mice is associated with an increased susceptibility to focalcerebral ischemia.

To gain an insight into the mechanism of the increase in infarct size in APP transgenics, we measured A $beta$ concentration inthe postischemic brain using a sensitive ELISA-based assay (Suzukiet al., 1994; Gravina et al., 1995). The rationale for this approachwas that global cerebral ischemia has been reported to increasethe cleavage of APP into the A $beta$ fragment in the gerbil hippocampus(Saido et al., 1994; Yokota et al., 1996). Because the A $beta$ peptideis thought to be neurotoxic (Mattson et al., 1993a; Fraser etal., 1997), accumulation of A $beta$ in the postischemic brain may exacerbatetissue damage. However, although relatively high levels of transgene-derivedA $beta$ were observed in the brain of APP mice, the concentration ofthis peptide did not differ between ischemic and nonischemic hemispheres.This finding argues against the hypothesis that ischemia increasesA $beta$ cleavage from APP. However, because A $beta$ was measured in theentire ischemic region, the possibility of increases in subregionsof the infarct cannot be ruled out. Studies in which A $beta$ is measuredregionally are required to address this issue.

To investigate the role of vascular factors in the increased susceptibility to cerebral ischemia of APP transgenics, we studiedthe reduction in CBF produced by MCA occlusion in APP mice andcontrols. It was found that, although in the center of the ischemicterritory the flow reduction is virtually identical in transgenicand nontransgenic mice, at the periphery of the infarct the degreeof oligemia is more marked in APP transgenics. The region in whichthe flow reduction is more severe overlaps with the area recruitedinto infarction in the transgenics. This area of the infarct correspondsto the "ischemic penumbra," a region in which the reduction inflow is not severe enough to produce rapid neuronal death (Astrupet al., 1981; Hakim, 1987; Hossmann, 1994). Therefore, the ischemicpenumbra can be rescued from infarction if flow is reestablished(e.g., Zhang and Iadecola, 1993; Overgard et al., 1994; Zhanget al., 1994). On the other hand, if the flow reduction becomesmore severe, or if the metabolic state of the tissue worsens,the penumbra undergoes infarction (e.g., Huang et al., 1996; Kimet al., 1996). Therefore, the observation that penumbral CBF isreduced to a greater extent in APP transgenics than in wild-typemice suggests that vascular factors play a role in the increasedsusceptibility to ischemic damage of APP transgenics.

To study the mechanisms by which APP leads to more severe oligemia in the penumbra, we studied cerebral vascular reactivityin the APP transgenics. We found that the vasodilation producedby neocortical application of ACh, a response mediated by localrelease of endothelial nitric oxide (Faraci, 1992; Wei et al.,1992), is reduced in these mice. The effect cannot be attributedto a nonspecific loss in vascular reactivity or to an impairmentof the response of vascular smooth muscles to nitric oxide, becausethe vasodilation produced by the nitric oxide donor SNAP was notaffected. These observations suggest that endothelial-dependentvascular responses are impaired in APP transgenics. This findingis in agreement with data demonstrating that in the rat aorta,endogenous A $beta$ reduces the vascular reactivity to acetylcholine(Thomas et al., 1996). Therefore, one possibility is that A $beta$ disruptscerebral vascular regulation and impairs the reactivity of thecerebral circulation to selected vasodilator stimuli. Such lossof vascular reactivity could explain the depression of CBF inthe penumbral region of the infarct found in the APP transgenics.After MCA occlusion, flow to the regions surrounding the ischemiccore is provided through collateral vessels from the adjacentnonischemic brain. Collateral flow develops because of vasodilatationof arterioles at the infarct border, a process that favors redistributionof flow toward the ischemic region (Iadecola, 1997). It is likely,therefore, that the loss of endothelium-dependent vascular reactivityin APP transgenics prevents the formation of an effective collateralcirculation and results in more severe ischemia in vulnerableregions of the ischemic penumbra. It remains to be determined,however, whether other aspects of cerebral endothelial function,such as the blood-brain barrier, are also altered in APP transgenicsand whether such alteration contributes to their increased susceptibilityto cerebral ischemia. The observation that the ischemic swellingdoes not differ between transgenic and nontransgenic mice suggeststhat the increase in cerebrovascular permeability that accompaniescerebral ischemia is not enhanced further by APP overexpression.Further studies will be required to investigate blood-brain barrierfunction in APP transgenics.

On the other hand, the increased susceptibility to ischemic damage in APP transgenics could also result from direct neurotoxiceffects of A $beta$ on the postischemic brain. We have shown here thattransgene-derived A $beta$ is present in a relatively high concentrationin the brain of APP mice. There is evidence that A $beta$ is neurotoxicand promotes excitotoxicity, effects mediated through free radicalformation and perturbation of ionic homeostasis (Mattson et al.,1993a; Fraser et al., 1997). Elevated levels of A $beta$ could, therefore,worsen brain damage by amplifying the pathogenic processes thatoccur during cerebral ischemia. An important question is whetherthe flow reduction in penumbra is secondary to the exacerbationof the tissue damage by A $beta$ . For the following reasons, however,this possibility is unlikely. First, the presence of impairedendothelium-dependent vascular reactivity in nonischemic APP transgenicsargues strongly that the cerebrovascular dysfunction is a directconsequence of a vascular action of A $beta$ and not a secondary effectof ischemic damage. Second, the worsening of penumbral blood flowoccurs within 30 min of induction of ischemia, at a time whencerebral ischemic damage is still in its early stages (Dereskiet al., 1993; Garcia et al., 1993). Therefore, secondary vasculareffects from tissue damage are unlikely at this time. Third, inmice in which there is an increase in focal ischemic brain damageattributed to direct neurotoxicity, for example in superoxidedismutase null mice, no effects on flow were observed (Kondo etal., 1997). These observations suggest that secondary effectsof A $beta$ -mediated neurotoxicity on vascular function are unlikely.

In conclusion, we have demonstrated that MCA occlusion in transgenic mice overexpressing APP produces infarcts that are largerthan in nontransgenic controls. Although the A $beta$ peptide is presentin the brain of APP transgenics, cerebral ischemia does not enhanceAPP cleavage and does not increase A $beta$ accumulation. In addition,MCA occlusion produces a more severe CBF reduction in the ischemicpenumbra of APP transgenics than in wild-type controls. This effectis related to a substantial loss in endothelium-dependent vascularreactivity in the transgenics. The data demonstrate that APP overexpressionincreases the susceptibility of the brain to ischemic damage.The effect is likely to involve both transgene-derived A $beta$ neurotoxicityand A $beta$ -induced vascular dysfunction, resulting in more severeischemia in regions at risk for infarction. The combination ofthese factors, therefore, contributes to the exacerbation of ischemicbrain damage. The vascular actions of APP metabolites have tobe taken into account in studies of the role of APP in neurodegenerationand neurotoxicity.

FOOTNOTES

Received June 13, 1997; revised July 22, 1997; accepted Aug. 5, 1997.

This work was supported by grants from the American Heart Association (C.I.) and National Institutes of Health Grants NS34179,NS31318, and NS35806 (C.I.) and NS33249 (K.K.H.). C.I. is an EstablishedInvestigator of the American Heart Association. We thank Dr. LennartMucke for his comments, Ms. Sara Love for helping with the transgenicmice, and Ms. Karen MacEwan for editorial assistance.

Correspondence should be addressed to Dr. C. Iadecola, Department of Neurology, University of Minnesota, Box 295 UMHC, 420Delaware Street Southeast, Minneapolis, MN 55455.

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