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Previous Article | Next Article
Volume 17, Number 18, Issue of September 15, 1997 pp. 6939-6946
Copyright ©1997 Society for NeuroscienceNeuroprotective Actions of FK506 in Experimental Stroke: In Vivo Evidence against an Antiexcitotoxic Mechanism
Steven P. Butcher1, David C. Henshall2, Yoshinori Teramura3, Kazuhide Iwasaki3, and John Sharkey1 1 Fujisawa Institute of Neuroscience and 2 Department of Pharmacology, University of Edinburgh, United Kingdom EH8 9JZ, and 3 Pharmaceutical and Pharmacokinetic Research Laboratory, Fujisawa Pharmaceutical Company, Limited, Osaka, Japan
ABSTRACT
The cellular mechanisms underlying the neuroprotective action of the immunosuppressant FK506 in experimental stroke remain uncertain, although in vitro studies have implicated an antiexcitotoxic action involving nitric oxide and calcineurin. The present in vivo study demonstrates that intraperitoneal pretreatment with 1 and 10 mg/kg FK506, doses that reduced the volume of ischemic cortical damage by 56-58%, did not decrease excitotoxic damage induced by quinolinate, NMDA, and AMPA. Similarly, intravenous FK506 did not reduce the volume of striatal quinolinate lesions at a dose (1 mg/kg) that decreased ischemic cortical damage by 63%. The temporal window for FK506 neuroprotection was defined in studies demonstrating efficacy using intravenous administration at 120 min, but not 180 min, after middle cerebral artery occlusion. The noncompetitive NMDA receptor antagonist MK801 reduced both ischemic and excitotoxic damage. Histopathological data concerning striatal quinolinate lesions were replicated in neurochemical experiments. MK801, but not FK506, attenuated the loss of glutamate decarboxylase and choline acetyltransferase activity induced by intrastriatal injection of quinolinate. The contrasting efficacy of FK506 in ischemic and excitotoxic lesion models cannot be explained by drug pharmacokinetics, because brain FK506 content rose rapidly using both treatment protocols and was sustained at a neuroprotective level for 3 d. Although these data indicate that an antiexcitotoxic mechanism is unlikely to mediate the neuroprotective action of FK506 in focal cerebral ischemia, the finding that intravenous cyclosporin A (20 mg/kg) reduced ischemic cortical damage is consistent with the proposed role of calcineurin.
Key words: FK506; tacrolimus; stroke; neuroprotection; excitotoxicity; ischemia; MK801; dizocilpine; cyclosporin A
INTRODUCTION
The immunosuppressant FK506 (tacrolimus, Prograf) recently has been introduced into clinical use for the prevention of allograft rejection. Its immunosuppressive mechanism involves inhibition of calcineurin (protein phosphatase 2B) by a complex of FK506 and the 12 kDa immunophilin FKBP12 (Liu et al., 1991
, 1992
Several lines of evidence indicate a role for immunophilins and/or calcineurin in brain function and development (Lyons et al., 1994
MATERIALS AND METHODS
Materials. Quinolinate (lot Q-1375) was purchased from Sigma (Poole, UK), NMDA and AMPA from Tocris Chemicals (Bristol, UK), and MK801 (dizocilpine) from Research Biochemicals (St. Albans, UK). Excitotoxins were dissolved in sterile 50 mM PBS, pH-adjusted to 7.4 with NaOH. Endothelin-1 (Nova Biochem: lot A13210) was dissolved in sterile saline. FK506 (Fujisawa Pharmaceutical, Osaka, Japan) was dissolved in 10% ethanol in 50 mM PBS containing 1% Tween 80 for intraperitoneal studies and in 10% ethanol in saline containing 400 mg/ml polyoxyl 60 hydrogenated castor oil for intravenous studies.
Excitotoxic lesions. Male Sprague Dawley rats (280-340 gm; Charles River, Margate, UK) were anesthetized with either pentobarbitone (Sagittal; 60 mg/kg) for intraperitoneal studies or halothane (4% for induction; 1-2% for maintenance) in nitrous oxide/oxygen (80/20%; v:v) for intravenous studies. Normothermia (37 ± 1°C) was maintained by using a thermostatically controlled heating blanket connected to a rectal thermometer. Excitotoxins were injected under stereotaxic guidance over 2 min into the striatum [anteroposterior (AP) +0.5 mm; mediolateral (ML) ± 3.0 mm; dorsoventral (DV) 4.5 mm below dura], cortex (AP +0.5 mm; ML
Induction of focal cerebral ischemia. Male Sprague Dawley rats (300-370 gm; Charles River) were anesthetized with either pentobarbitone (Sagittal; 60 mg/kg) for intraperitoneal studies or halothane (4% for induction; 1-2% for maintenance) in nitrous oxide/oxygen (80/20%; v:v) for intravenous studies. Normothermia (37 ± 1°C) was maintained by using a thermostatically controlled heating blanket connected to a rectal thermometer. Endothelin-1 (60 pmol in 3 µl) was injected via a 31-gauge guide cannula stereotaxically placed 0.5 mm above the middle cerebral artery (AP +0.2 mm; ML
Histopathological assessment of brain damage. Rats were reanesthetized with pentobarbitone (Sagittal; 60 mg/kg) 3 d after injection of excitotoxins or middle cerebral artery occlusion (MCAO) and were fixed by transcardiac perfusion first with 20 ml of heparinized saline (10 U/ml), followed by 200 ml of 4% paraformaldehyde in 50 mM PBS, pH 7.4. The brain was removed intact and immersed in fixative containing 10% sucrose for at least 24 hr before cryostat sectioning. Coronal sections (20 µm thick) were cut and stained with either cresyl violet or thionine. The volume of brain damage was determined as described previously (Park et al., 1989
Measurement of glutamate decarboxylase (GAD) and choline acetyltransferase (ChAT) activity. Rats were killed by cervical dislocation 3 d after intrastriatal injection of quinolinate injection. The brain was removed immediately, and injected and uninjected striata were dissected and homogenized in 20 vol of ice-cold water containing 1 mM EDTA and 0.1% Triton X-100, pH 7.4. Tissue GAD and ChAT activity was determined by using minor modifications of the methods of Kanazawa et al. (1976)
Measurement of mean arterial blood pressure (MABP) and rectal and brain temperature. Separate groups of animals were anesthetized with halothane (4% for induction; 1-2% for maintenance) in nitrous oxide/oxygen (80/20%; v:v) and placed in a stereotaxic frame. An intravenous catheter was inserted in the femoral artery and connected via a pressure transducer to a Kontron Supermon monitor for measurement of MABP. Rectal temperature was measured by a thermometer inserted 9 cm into the rectum, which was connected to a thermostatically controlled heating blanket. Brain temperature was measured by a miniature thin film recording probe (Ottosensor, Cleveland, OH) inserted into the striatum (AP +1.0 mm; ML
Measurement of brain and blood FK506 content. Nonfasted rats were injected with FK506 by the intravenous (1 mg/kg) or intraperitoneal (10 mg/kg) route. Rats were anesthetized with halothane at the specified time points between 15 min and 72 hr later, and a venous blood sample was collected from the vena cava. Then the vasculature was flushed with 20 ml of heparinized saline via an intra-aortic cannula. Animals were decapitated immediately, and the whole brain (minus cerebellum and brainstem) was dissected. Blood and brain samples were stored at
FK506 was measured by competitive enzyme immunoassay with a mouse anti-FK506 monoclonal antibody (FKmAb) and FK506-conjugated peroxidase (FK-POD). FK506 in whole blood was extracted with methanol. Brain samples were homogenized in distilled water (10%, w:v), and FK506 was extracted with n-hexane containing 2.5% isoamyl alcohol. The extraction solvent was evaporated and the residue dissolved in FK-POD solution. The solution was added to a microtiter plate well, coated previously with goat anti-mouse IgG polyclonal antibody, and was mixed with FKmAb to determine competitive binding of FK506 and FK-POD with FKmAb. POD activity was measured using o-phenylenediamine and hydrogen peroxide as cosubstrates. The reaction was stopped by addition of H2SO4, and optical density was measured by a microplate reader (Molecular Devices, Menlo Park, CA). FK506 content was determined by comparison with a standard curve.
RESULTS
Intraperitoneal drug administration
The effects of intraperitoneal pretreatment with FK506 and the noncompetitive NMDA receptor antagonist MK801 (dizocilpine) on the volume of brain damage associated with endothelin-induced MCAO, an experimental model of stroke, were evaluated. MK801 (5 mg/kg), administered intraperitoneally 30 min before vessel occlusion, decreased the volume of ischemic damage in the cortex by 50% (Fig. 1). Similarly, FK506 reduced ischemic damage in cortex by 56 and 58% at 1 and 10 mg/kg, respectively (Fig. 1). Neither drug decreased the volume of ischemic brain damage in striatum (data not shown).
Fig. 1. Neuroprotection studies used intraperitoneal drug administration 30 min before lesion induction. MK801 (MK3; 3 mg/kg) inhibited excitotoxic brain damage in striatum, hippocampus, and cortex induced by quinolinate (100 nmol, striatum; 50 nmol, hippocampus and cortex) and NMDA (100 nmol), and at 5 mg/kg (MK5) it reduced the volume of cortical damage induced by MCAO. FK506 (1 and 10 mg/kg; FK1 and FK10, respectively) inhibited ischemic damage, but it had no effect on excitotoxic damage. Neither drug reduced excitotoxic damage in striatum induced by AMPA (25 nmol). Data are the mean volume of brain damage (± SEM) for groups of 5-12 animals. Statistical comparisons between drug and vehicle (saline, S; FK506 vehicle, V) groups used unpaired t tests for excitotoxin data and ANOVA with post hoc Scheffé's analysis for MCAO data (*p < 0.05; **p < 0.01; ***p < 0.001).
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Excitotoxic striatal lesions were produced by injection of quinolinate, NMDA, or AMPA, with regional specificity evaluated by using quinolinate lesions in hippocampus and cortex. The excitotoxin doses that were used produced submaximal lesions in terms of the volume of brain damage (30-50% of maximal neuronal damage; data not shown). MK801 (3 mg/kg), administered intraperitoneally 30 min before excitotoxin injection, reduced the volume of quinolinate-induced damage in striatum, hippocampus, and cortex by 87, 95, and 37%, respectively (Fig. 1). The smaller decrease in cortex was attributable to proportionally more nonspecific damage being caused by needle penetration. The NMDA-induced striatal lesion was 82% smaller in MK801-treated rats, whereas the volume of the AMPA-induced lesion was unaffected (Fig. 1). With the use of an identical intraperitoneal administration protocol, FK506 (1 and 10 mg/kg) did not reduce the volume of excitotoxic brain damage induced by quinolinate, NMDA, or AMPA (Fig. 1). Intravenous drug administration
MK801 (0.3 mg/kg) and FK506 (1 mg/kg) decreased the volume of ischemic brain damage in cortex after endothelin-induced MCAO by 34 and 58%, respectively (Fig. 2). In contrast to previous negative data obtained using 1 mg/kg cyclosporin A (Sharkey and Butcher, 1994
Fig. 2. Neuroprotection studies used intravenous drug administration 1 min after lesion induction. FK506 (FK1; 1 mg/kg), MK801 (MK0.3; 0.3 mg/kg) and cyclosporin A (Cs20; 20 mg/kg) reduced the volume of ischemic brain damage in cortex, but not striatum, induced by MCAO. The volume of excitotoxic brain damage in striatum induced by quinolinate (100 nmol) was reduced by MK801 (0.3 mg/kg), whereas FK506 (1 mg/kg) was ineffective. Data are the mean volume of brain damage (± SEM) for groups of 5-12 animals. Statistical comparisons between drug and vehicle (saline, S; FK506 vehicle, V) groups used unpaired t tests for excitotoxin data and ANOVA with post hoc Scheffé's analysis for MCAO data (*p < 0.05; **p < 0.01; ***p < 0.001).
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GAD and ChAT activity
GAD activity, a marker for striatal GABAergic interneurons, was reduced by 44% (p < 0.05) from 4.37 ± 0.49 µmol/mg protein/hr in the contralateral striatum of vehicle-treated rats to 2.47 ± 0.27 µmol/mg protein/hr in the quinolinate-injected striatum (Fig. 3). GAD activity in the quinolinate-injected striatum of rats treated with FK506 using intraperitoneal (10 mg/kg; 30 min pretreatment) and intravenous (1 mg/kg; 1 min after excitotoxin injection) administration protocols was reduced by 44% (p < 0.05) and 46% (p < 0.05), respectively, as compared with the contralateral striatum (Fig. 3). In contrast, GAD activity was not reduced significantly in the quinolinate-injected striatum of MK801-treated rats using intraperitoneal (3 mg/kg) and intravenous (0.3 mg/mg) drug administration (Fig. 3). Similar data were obtained by using a ChAT assay to determine the survival of striatal cholinergic neurons. In this case, enzyme activity was reduced by 45% (p < 0.05) from 746 ± 94 nmol/mg protein/hr in the contralateral striatum of vehicle-treated rats to 413 ± 83 nmol/mg protein/hr in the quinolinate-injected striatum. ChAT activity in the quinolinate-injected striatum of rats treated with FK506 using intraperitoneal and intravenous administration protocols was reduced by 37% (p < 0.05) and 38% (p < 0.05), respectively, as compared with the contralateral striatum. ChAT activity was not decreased significantly in the quinolinate-injected striatum of MK801-treated rats; reductions of 9 and 25% were noted with intraperitoneal and intravenous drug administration, respectively, as compared with the contralateral striatum.
Fig. 3. Effects of intrastriatal quinolinate injection on glutamate decarboxylase activity in striatal homogenates. When administered intraperitoneally 30 min before intrastriatal injection of 100 nmol quinolinate, MK801 [MK (i.p.); 3 mg/kg], but not FK506 [FK (i.p.); 10 mg/kg], prevented the reduction of enzyme activity noted in the quinolinate-injected hemisphere. Similarly, with intravenous administration 1 min after excitotoxin injection, MK801 [MK (i.v.); 0.3 mg/kg], but not FK506 [FK (i.v.); 1 mg/kg], prevented the reduction in enzyme activity. Data are mean enzyme activity (± SEM) in contralateral uninjected (open bars) and quinolinate-injected (filled bars) striata for groups of four animals. Statistical comparisons of enzyme activity in the two hemispheres were performed by using a paired t test (*p < 0.05; **p < 0.01).
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Delayed intravenous administration of FK506
The temporal window of therapeutic efficacy for FK506 with regard to its neuroprotective action was characterized in a separate group of animals. Although intravenous injection of FK506 (1 mg/kg) at 1, 60, and 120 min after endothelin-induced MCAO reduced the volume of cortical brain damage by 48, 46, and 57%, respectively, FK506 was ineffective when administered after 180 min (Fig. 4). FK506 did not reduce the volume of striatal damage at any time point studied (data not shown). A substantial increase in the volume of ischemic brain damage also was noted in vehicle-treated rats as the duration of anesthesia was extended (Sharkey and Butcher, 1995
Fig. 4. The temporal window of neuroprotective efficacy for intravenous FK506 (1 mg/kg) administered after endothelin-induced MCAO. Data are the mean volume of ischemic brain damage (± SEM) in cortex for groups of 8-12 animals from vehicle (open bars) and FK506-treated (filled bars) rats. Statistical comparisons were performed by using ANOVA with post hoc Scheffé's analysis (*p < 0.05 comparison of drug and vehicle groups;p < 0.05 comparison of vehicle groups with the 1 min vehicle group).
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Physiological variables
MABP was monitored from 30 min before endothelin-induced MCAO until 180 min after vessel occlusion in animals treated intravenously with either FK506 (1 mg/kg) or FK506 vehicle; significant effects on MABP were not noted in either group (Fig. 5). Rectal and brain temperature similarly were unaffected after endothelin-induced MCAO in FK506 and vehicle-treated rats (Fig. 5).
Fig. 5. Endothelin-induced MCAO in FK506 (filled circles) and vehicle-treated (open circles) rats does not affect the mean arterial blood pressure (MABP) nor rectal or intracerebral temperatures. Rats were anesthetized continuously with halothane with measurements made from 30 min before until 180 min after vessel occlusion. Data are mean values (± SEM) from four rats per group. P is the mean preocclusion value; endothelin was injected at time 0, and FK506 (1 mg/kg) was administered intravenously 1 min after vessel occlusion. Statistical comparisons were performed by using ANOVA with post hoc Scheffé's analysis (p < 0.05).
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Brain and blood levels of FK506
Brain and blood levels of FK506 were determined from 15 min until 72 hr after intraperitoneal (10 mg/kg) and intravenous (1 mg/kg) administration (Fig. 6). With the use of the intravenous administration route, a brain content of ~50 ng/gm tissue was detected throughout the monitoring period (Fig. 6). In contrast, the blood level of FK506 fell rapidly in an exponential manner from 163 ng/ml at 15 min postinjection to an undetectable level at 72 hr. A slightly different pattern was noted with the intraperitoneal administration route (Fig. 6). The brain content of drug rose to a maximum of ~400 ng/gm tissue at 12 hr after injection and thereafter fell slightly to 300 ng/gm tissue at 72 hr. It should be noted that a brain content of 135 ng/gm tissue was detected 30 min postinjection, the time at which the excitotoxic or ischemic challenge was initiated using this route of drug administration. The blood level of drug was maximal 15-30 min after injection, with FK506 levels falling rapidly thereafter to a trough level of 2 ng/ml detected at 48-72 hr.
Fig. 6. Brain and blood levels of FK506 after intravenous (1 mg/kg) and intraperitoneal (10 mg/kg) dosing. Data are mean brain (filled circles) and blood (open circles) FK506 content (± SEM) from four animals per group. Histograms show FK506 content in cortical samples obtained 1 and 3 hr after endothelin-induced middle cerebral artery occlusion. Data are mean cortical FK506 content (± SEM) in the nonischemic (open bars) and ischemic (filled bars) hemisphere from four animals per group.
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Cortical FK506 content also was measured following endothelin-induced MCAO with intravenous drug (1 mg/kg) administration 5 min after vessel occlusion (Fig. 6). Drug content in the contralateral nonischemic cortex was 36.8 ± 6.83 and 37.4 ± 4.54 ng/gm tissue at 1 and 3 hr, respectively, after vessel occlusion. FK506 content in the ischemic cortex was not significantly different: 28.6 ± 2.87 ng/gm tissue and 38.5 ± 7.7 ng/gm tissue at 1 and 3 hr, respectively. Blood levels of FK506 in these animals were 47.3 ± 3.58 and 24.1 ± 3.38 ng/ml, respectively.
Further neuroprotection experiments were performed to ascertain whether the FK506 detected in brain 24-72 hr after a single intravenous injection was bioavailable. FK506 (1 mg/kg, i.v.) was administered either 24 or 72 hr before endothelin-induced MCA occlusion, and the volume of ischemic brain damage was determined 72 hr after vessel occlusion. The volume of ischemic brain damage in cortex was reduced by 64% (p < 0.05) and 39% (p < 0.05) from 132 ± 20 mm3 in vehicle-treated rats (n = 11) to 47 ± 8 mm3 (n = 10) and 82 ± 10 mm3 (n = 11) in animals pretreated with FK506 for 24 and 72 hr, respectively.
DISCUSSION
The present study confirms that FK506 exhibits a powerful neuroprotective action in an experimental model of stroke (Sharkey and Butcher, 1994
Pharmacokinetic findings suggest that differences in the time course of excitotoxic and ischemic damage cannot explain the contrasting efficacy of FK506. The brain content of FK506 rose rapidly after intravenous dosing and was maintained at a constant level from 15 min after injection until the experimental endpoint 72 hr later. The similar degree of neuroprotection afforded by FK506 pretreatment either 24 or 72 hr before MCAO and by drug treatment immediately after vessel occlusion confirmed the bioavailability of FK506 detected in pharmacokinetic studies. Although these findings rule out the possibility that excitotoxins exert an action in the brain that outlives the half-life of the drug, an effective concentration of drug might be required immediately postinsult to observe an antiexcitotoxic effect. This is unlikely because intraperitoneal administration of FK506, at a dose that attenuated ischemic but not excitotoxic damage, resulted in a brain content of drug in excess of that required for ischemic neuroprotection using intravenous dosing, from the time of the excitotoxic challenge (30 min after intraperitoneal FK506 administration) until the experimental endpoint. The finding that FK506 content was similar in ischemic and nonischemic cortex was also of interest. These data indicate that the bioavailability of FK506 must be high because the drug penetrates readily into ischemic tissue and suggest that there is no gross perturbation of the blood-brain barrier in the endothelin model of focal cerebral ischemia.
Physiological data concerning MABP and rectal and brain temperature provided no clue to the neuroprotective mechanism of FK506 in experimental stroke. MABP was unaffected by FK506, and whereas body and brain temperature influence the severity of brain damage after focal cerebral ischemia (Morikawa et al., 1992
Further evidence to support the proposed role of calcineurin in the neuroprotective mechanism of FK506 was provided by the finding that 20 mg/kg cyclosporin A reduced ischemic brain damage. Subchronic pretreatment with equivalent doses of cyclosporin A previously had been reported to decrease brain edema after MCAO (Shiga et al., 1992 -diphosphoribose) synthetase (PARS), ATP depletion, and cell death (Zhang et al., 1994
An alternative mechanism involving peroxynitrite, a neurotoxic free radical produced from nitric oxide and superoxide (Lipton et al., 1993
FOOTNOTES
Received March 4, 1997; revised June 25, 1997; accepted July 9, 1997.
This work was supported by Fujisawa Pharmaceutical, Osaka, Japan, and The James A. Kennedy Bequest Fund.
Correspondence should be addressed to Dr. Steve Butcher, Fujisawa Institute of Neuroscience, Department of Pharmacology, University of Edinburgh, 1 George Square, Edinburgh EH8 9JZ, UK.
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