Protective effects of D‑Limonene against transient cerebral ischemia in stroke‑prone spontaneously hypertensive rats
- Authors:
- Published online on: November 14, 2017 https://doi.org/10.3892/etm.2017.5509
- Pages: 699-706
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Copyright: © Wang et al. This is an open access article distributed under the terms of Creative Commons Attribution License.
Abstract
Introduction
Stroke is a leading cause of disability and death world-wide and it is lack of effective treatments for acute stroke. Cerebral small vessel disease (CSVD) contributes to only 20–30% of all strokes (1), and it substantially increases the risk of stroke in the future (2) and accounts for about 45% of dementia cases (3). Progressive CSVD and stroke lead to decline of cognition, causing a major burden on the individual and the healthcare system (4,5). One in three U.S. adults-67 million people-is estimated to have high blood pressure, which if not controlled can result in CSVD and cause cerebral stroke (6). Stroke-prone spontaneously hypertensive (SHRsp) rats, derived from Wistar-Kyoto (WKY) rats, serve as a widely-used model of severe hypertension, given that the rats naturally progress to hypertension starting from 4 weeks to 12 weeks of age (7,8) and more than 95% of rats die of stroke (9). In SHRsp rats, cerebral blood flow could be reduced by severe hypertension and monocyte adhesion to the cerebral artery endothelium can be increased (10). The increased blood pressure induces cerebral vasogenic oedema (11).
D-Limonene, a common natural monocyclic monoterpene, also known as 1-methyl-4-(1-methyl ethenyl) cyclohexene, which is widely distributed as a natural nonnutritive constituent in a variety of foods, including fruits (citrus fruits, especially lemon and orange) (12), vegetables (carrots) (13), coffee, beverages, meat, and spices (nutmeg) (14). It is found naturally in orange juice at an average concentration of 100 mg/l (15). D-Limonene is usually used as a lemon fragrance in soaps, lotions, creams, detergents, and perfumes and as a flavoring agent in foods, beverages, and chewing gum (15). In the last years, numerous studies have found that D-limonene possesses powerful antioxidative properties and protects organisms from oxidative damage (16,17). In addition, D-limonene exhibits antitumorigenic, hepatoprotective, immunomodulatory, and anti-inflammatory properties (18–22). In particular, D-limonene has been shown to attenuate stress-induced hypertension and stress responses in SHRsp rats (23,24). However, the effect of D-limonene on cognitive and memory function and ischemic injury in SHRsp rats is not clear.
The present study aimed to evaluate the therapeutic efficacy of D-limonene against the ischemia-resulted injury of cognitive and memory and behavioral function and vascular remodeling. We showed that D-limonene substantially attenuated the decline of cognitive and memory and behavioral function and ischemic injury in SHRsp rats.
Materials and methods
Animals and treatment
WKY and SHRsp rats were purchased from SLK (Shanghai, China) and then maintained in rooms under conditions of controlled temperature (21±2°C), humidity (60±10%), and a 12 h light/dark cycle (exposed to artificial light from 7:00 am to 7:00 pm) and air ventilation (15 min/h). The rats were fed with a standard rodent laboratory diet and water ad libitum. Adequate measures were taken to minimize pain or discomfort, and the experiments were carried out in accordance with the conventional guidelines for experimentation with animals (National Institute of Health, Publication no. 85-23, revised 1996). All animal procedures were approved by the Review Board of Puai Hospital of Tongji Medical College, Huazhong University of Science and Technology.
After 1 week acclimatization, male 15-week old rats with stroke surgery were randomly allocated the following groups: (1) WKY: sham control (n=16); (2) SHRsp: hypertensive sham (SHRSP alone, n=16); (3) SHRSP undergoing transient middle cerebral artery occlusion (tMCAO) for 60 min and receiving vehicle (SHRSP + tMCAO, n=16); (4) SHRSP undergoing tMCAO and treated with D-limonene (SHRSP + tMCAO + D-limonene, n=16). 1 h after the induction of tMCAO, animals were treated with 20 mg/kg of D-limonene (97%; Sigma-Aldrich, St. Louis, MO, USA) intraperitoneally once daily for 14 days. The dose of D-limonene used in the study was selected according to our preliminary results and previous studies (25,26). We have observed mild liver toxicity of 50 mg/kg D-limonene in mice.
Transient cerebral ischemia induced by occlusion of the right middle cerebral artery (MCA) was performed as previous described (27,28). A midline incision was cut on the ventral surface of the neck to expose the right common carotid arteries which were ligated with 6.0 silk suture. The internal carotid and pterygopalatine artery were temporarily occluded for 60 min using a microvascular cliRelative cerebral blood flow (CBF) was monitored during the process of occlusion. After the 60 min of tMCAO, reperfusion was allowed by withdrawing the occluding filament back into the common carotid artery. Relative CBF was then monitored for 5 min and then the wound was sutured and the rats were then permitted to recover from anesthesia. Drug treatment was performed 5 min before the reperfusion. Sham-operated WKY and SHRSP rats were subjected only to exposure of the carotid arteries but not the occlusion.
Blood pressure measurement
Systolic blood pressure was determined in quiet conditions by means of the tail-cuff method after warming up the apparatus platform to 37°C for 10 min. Each rat was introduced into a restrainer and a blood pressure tail-cuff was affixed to the base of the tail.
Morris water maze test
The Morris water maze test was conducted to evaluate the memory and cognitive function in rats. The Morris water maze test was performed as previously. In brief, a circular pool (1.3 m in diameter, 50 cm in depth) was filled with room-temperature water. 1 cm below the surface of the water, a transparent platform was placed in the southeastern quadrant. On the first day, the rats were put into the pool without the platform for 2 min to get used to the experimental environment. Over the next 4 days, the platform acquisition test was conducted 4 times per day. The rats were released from different starting points and allowed to swim for 60 s to search for the platform. The escape latency time was defined by the time spent to find the hidden platform by the rats and times longer than 60 s were recorded as 60 s. 24 h later, the rats were released from a new start position in the pool without the platform, which was termed the probe trial. The amount of time spent in the southeastern quadrant was recorded.
Novel object recognition test
The rats were individually placed into a plastic box with two objects with different forms. The rats were allowed to freely move in the box for 5 min. This adaptive training was conducted again after 180 min. In the short-term memory test, we replace one of the objects 180 min after the second training. The time spent by each animal with the novel object and the familiar object was recorded during a 10 min test period. In the long-term memory test, we replace the novel object 24 h after the second training. The time spent by each rat with the novel object and the familiar object was again recorded during a 10 min test period. In the tests, exploration was defined as sniffing or touching the object with the nose or foreleg. the objects were washed after each test to to avoid olfactory perception by the next rat.
Behavioral tests
Grip strength
The degree of force necessary to make the animal release a pull grid assembly with its forepaw was evaluated using a grip strength meter (Columbus Instruments, Columbus, OH, USA) as previously described (28). For each rat, a digital reading (in Newtons) of two successive trials was recorded and analyzed.
Somatosensory neglect test
The sensory impairments were detected by measurement of the detection of, and reaction to, small pieces of adhesive tape applied to the forelimbs after MCAO. We place a removable sticky tape on the ventral side of the animal's paw contralateral to the induced stroke. The time spent by each rat to contact or sense the tape and the time spent to remove it was recorded for 180 s. Two successful trials for each animal were recorded for averaged analysis.
Spontaneous locomotor activity
Spontaneous motor activity was examined by Digiscan activity-monitoring boxes (AccuScan Instruments, Columbus, OH, USA). Each test was performed under red-light condition and lasted 5 min.
Measurement of infarct volume
Rats were deeply anesthetized using isoflurane. Transcardial perfusion was conducted using cold saline followed by 10% buffered formalin. Brains were collected and then fixed in gradient sucrose solution, and cut coronally into 20-µm sections as previously described (29).
Quantitative real-time PCR
Total RNA was extracted from brains using a RNA isolation kit and then reversely transcribed into cDNA using an miScript II RT Kit (Thermo Fisher Scientific Inc., Waltham, MA, USA), according to the manufacturer's instructions. cDNA was used as a template in PCR reactions using gene-specific primer pairs. Real-time PCR was performed using an miScript SYBR Green PCR Kit (Thermo Fisher Scientific Inc., Waltham, MA, USA). β-actin was used as endogenous control. The fold changes of target gene expression were determined with the ΔΔCt method, and the relative expression of these genes was calculated by the 2−ΔCT method and normalized to β-actin. IL-1 β forward primer: 5′-CAGGCTTCGAGATGAACAACAA-3′, and reverse primer: 5′-GTCCATTGAGGTGGAGAGCTTT-3′. MCP-1 forward primer: 5′-CTGTCACGCTTCTGGGCCTGT-3′, and reverse primer: 5′-GCAGCAGGTGAGTGGGGCAT-3′. COX-2 forward primer: 5′-CCAGAGCAGAGAGATGAAATACCA-3′, and reverse primer: 5′-GCAGGGCGGGATACAGTTC-3′. VEGF forward primer: 5′-GATGAGATAGAGTATATCTTCAAGCCGT-3′, and reverse primer: 5′-TCTATCTTTCTTTGGTCTGCATTCAC-3′. β-actin forward primer, 5′CTCCTGCTTGCTGATCCACATC-3′, and reverse primer: 5′-CCACTGCCGCATCCTCTT-3′.
Oxidative stress
Superoxide dismutase (SOD) and catalase (CAT) and the levels of glutathione (GSH) and malondialdehyde (MDA) were determined using assay kits purchased from Nanjing Jiancheng Company (Jiangsu, China) as per the manufacturer's protocols. 20-µm thick frozen brain sections were incubated with dihydroethidium (DHE) (10 µM) (Invitrogen, Carlsbad, CA) in PBS for 30 min at 37°C in a humidified chamber in dark environment. The DHE-positive cells were observed under a fluorescence microscope and the positive cells were counted using with Image J software and expressed as percentage of control.
Statistical analysis
Data were expressed as mean ± SEM. Data was analyzed using Graph Pad Prism software by one-way analysis of variance followed by a Turkey test for multiple comparisons. P<0.05 was considered to be statistically significant.
Results
D-Limonene reduces blood pressure in SHRsp rats after stroke
Body weights were not significantly different between WKY and SHRsp rats (Fig. 1A). Stroke resulted in a marked decrease of body weight (Fig. 1A). D-Limonene did not significantly alter the body in SHRsp rats after stroke (Fig. 1A). The systolic blood pressure in SHRsp rats was significantly higher than that in WKY rats (Fig. 1B). Stroke did not result in a remarkable increase of systolic blood pressure in SHRsp rats (Fig. 1B). D-Limonene protected against the increase of systolic blood pressure SHRsp rats after stroke (Fig. 1B).
D-Limonene attenuates memory and cognitive impairment in SHRsp rats after stroke
The function of memory and cognition was evaluated by means of Morris water maze test and novel object recognition test. On the first day, no significant difference was observed in the hidden platform acquisition test among different groups. On the 3–5 days, the escape latency time in SHRsp rats was remarkably longer, compared with the WKY rats (Fig. 2A-E). Stroke resulted in a significant increase of escape latency time in SHRsp rats (Fig. 2A-E). The administration of D-Limonene markedly decreased the escape latency time in SHRsp rats after stroke (Fig. 2A-E). SHRsp rats spent less time in the target quadrant in the probe trial than that in WKY rats (Fig. 2F). Stroke resulted in a significant decrease of time spent in the target quadrant in the probe trial in SHRsp rats (Fig. 2F). The administration of D-Limonene markedly increased the time spent in the target quadrant in the probe trial in SHRsp rats after stroke (Fig. 2F).
In the novel object recognition tests, there was a marked decrease in the capacity to distinguish between familiar objects and novel objects in the SHRsp rats, compared with that in WKY rats (Fig. 2G and H). Stroke resulted in a significant decrease of in the capacity to distinguish between familiar objects and novel objects in the SHRsp rats (Fig. 2G and H). The administration of D-Limonene markedly increased the capacity to distinguish between familiar objects and novel objects in the SHRsp rats in the short and long term memory tests (Fig. 2G and H).
D-Limonene attenuates behavioral impairment and infarct size in SHRsp rats after stroke
The behavioral tests were performed to evaluate the effect of D-Limonene on behavioral impairment in SHRsp rats after stroke. Grip strength in SHRsp rats was lower than that in WKY rats (Fig. 3A). Stroke resulted in a significant decrease of grip strength in the SHRsp rats (Fig. 3A). The administration of D-Limonene markedly increased grip strength in SHRsp rats after stroke (Fig. 3A). There was no significant difference of sensory neglect between SHRsp and WKY rats (Fig. 3B). Stroke resulted in a significant increase of sensory neglect in the SHRsp rats (Fig. 3B). The administration of D-Limonene markedly decreased sensory neglect in SHRsp rats after stroke (Fig. 3B). In the test of spontaneous motor activity, the distance travelled by SHRsp rats was significantly increased (Fig. 3C). However, stroke and D-Limonene had no significant effect on the distance travelled by the rats in SHRsp group (Fig. 3C). Ischemia-induced infarct volume in SHRsp rats was evaluated. As shown in Fig. 3D, the infarct volume induced by ischemia was significantly reduced by D-Limonene administration.
D-Limonene attenuates inflammation and increases angiogenesis in SHRsp rats after stroke
As shown in Fig. 4A-C, the mRNA expression of IL-1β, monocyte chemoattractant protein-1 (MCP-1) and cyclooxygenase-2 (COX-2) was significantly higher in the brain of SHRsp rats compared with that of WKY rats. Stroke resulted in a significant increase in the mRNA expression of IL-1β, MCP-1 and COX-2 in the SHRsp rats (Fig. 4A-C). The administration of D-Limonene markedly decreased the mRNA expression of IL-1β, MCP-1 and COX-2 in SHRsp rats after stroke (Fig. 4A-C). As shown in Fig. 4D, the mRNA expression of vascular endothelial growth factor (VEGF) was significantly decreased in the brain of SHRsp rats compared with that of WKY rats. Stroke resulted in a significant decrease in the mRNA expression of VEGF in the SHRsp rats (Fig. 4D). The administration of D-Limonene markedly increased the mRNA expression of VEGF in SHRsp rats after stroke (Fig. 4D).
D-Limonene attenuates oxidative stress in SHRsp rats after stroke
The effect of D-Limonene on oxidative stress under stroke condition was determined. As shown in Fig. 5, in SHRsp rats, the activities of antioxidant enzymes, including SOD (A) and CAT (B), was decreased, the level of MDA (C) was increased, the level of GSH (D) was decreased, and DHE-staining (E) was increased. Stroke resulted in a decrease of the activities of SOD and CAT, an increase of MDA, a decrease of GSH and an increase of DHE-staining (Fig. 5). The administration of D-Limonene markedly increased the activities of SOD and CAT, decreased the levels of MDA, increased the GSH level and decreased the DHE-staining in SHRsp rats after stroke (Fig. 5).
Discussion
Previous studies have showed that D-Limonene can reduce monocrotaline-induced pulmonary hypertension (30). Natural products containing D-Limonene have been shown to attenuate stress-induced hypertension and stress responses in SHRsp rats (23,24). In our study, we examined the effect of D-Limonene on changes of hypertension and ischemia-resulted neurological and vascular impairment in SHRsp rats. We showed that although the systolic blood pressure was not altered by ischemia operation, D-Limonene significantly decreased the systolic blood pressure in SHRsp rats after stroke. The administration of D-Limonene notably decreased the escape latency time and increased the time spent in the target quadrant in the probe trial in Morris water maze test, and markedly increased the capacity to distinguish between familiar objects and novel objects in the SHRsp rats in the short and long term memory tests. The results suggested that D-Limonene protected against ischemia-induced memory and cognitive impairment under the condition of hypertension.
It has been shown that D-Limonene may inhibit stimulant-induced behavioral changes via regulating dopamine levels and 5-HT receptor function (31). In the current study, we also evaluated the effect of D-Limonene on behavioral changes in SHRsp rats after stroke. We found that the administration of D-Limonene markedly increased grip strength and decreased sensory neglect in SHRsp rats after stroke, indicating that D-Limonene protected against ischemia-induced behavioral impairment under the condition of hypertension. The improvement of functional deficits could be attributed to the attenuation of infarct size after stroke.
Although the exact mechanisms and signaling pathways not clear, cerebral inflammation is implicated in the pathogenesis of hypertension and stroke. After transient cerebral ischemia, macrophages could be activated and produced IL-1β, which is an important mediator of neurodegeneration. Increase of cytokines and regulators play critical roles in cerebral vascular damage and stroke injury. In the study, we found that D-Limonene inhibited the increase of IL-1β, MCP-1 and COX-2 in SHRsp rats after stroke, indicating the amelioration of cerebral inflammation.
Vascular remodeling after stroke is an important process for neural regeneration (32,33). Under the condition of hypertension, VEGF expression is reduced, resulting in reduction of nitric oxide production and leading to vascular constriction and reduction in sodium ion renal excretion (34). We found that stroke-resulted reduction of VEGF expression was significantly inhibited by D-Limonene. We speculated that D-Limonene may promote vascular remodeling through upregulation of VEGF expression.
SHRsp rats can produce more hydroxyl radicals than WKY rats, making them more vulnerable to oxidant damage after transient ischemic stroke (9). Attenuation of ROS levels has been shown to promote hypertensive cerebral vessel remodeling (35). Increase of ROS production, resulting in oxidative stress and playing critical roles in a variety of brain and neurological diseases. Previous studies have shown that D-Limonene have potential antioxidant activities under different conditions. In the current study, we also found that D-Limonene exhibited potent antioxidant effects through increasing SOD and CAT activities, decreasing MDA levels, increasing GSH levels and decreasing ROS levels. The results suggested that the antioxidant role of D-Limonene may be involved in the protective effects against neurological and vascular impairment in SHRsp rats after stroke.
In conclusion, we found that D-Limonene decreased blood pressure in ischemia-treated SHRsp rats and protected against memory and cognitive and behavioral impairment in SHRsp rats after stroke. Inhibition of cerebral inflammation, vascular remodeling and antioxidant activities of D-Limonene may be involved in the protective effects against ischemia-induced damage in SHRsp rats. In future studies, more attention should be paid to explore the molecular mechanism and find the target of D-Limonene. Overall, our study identified D-Limonene as a potential therapeutic candidate for treatment of stroke-resulted cerebral and vascular damage under the condition of hypertension.
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