- *Corresponding Author:
- K. P. Singh
Defence Institute of Bio-Energy Research (DIBER), DRDO, Field Station, Pithoragarh-262 501, India
E-mail: kpvet@rediffmail.com
Date of Submission | 25 July 2013 |
Date of Revision | 21 August 2014 |
Date of Acceptance | 25 August 2014 |
Indian J Pharm Sci 2014;76(5):458-461 |
Abstract
The present study was aimed to evaluate the effect of natural specimen and laboratory cultured mycelia of Cordyceps sinensis on neuromuscular activity in mice. The powder of natural specimen and laboratory cultured Cordyceps sinensis was orally administered at the dose rate of 100, 300 and 500 mg/kg for 30 days. Natural specimen and in vitro propagated Cordyceps sinensis showed significant (P<0.05) enhancement in neuromuscular endurance and antidepressant activity at 300 and 500 mg/kg as compared to the control group. However, the fungus did not proved to be as effective as fluoxetine in exhibiting antidepressant action. Muscular endurance was determined on a Rota rod apparatus while antidepressant (mood elevating) activity was measured on a photoactometer in Swiss albino mice. The effects produced by both natural specimens and laboratory cultured Cordyceps sinensis were comparable and showed almost equal potency.
Keywords
Enhancement, Neuromuscular, Cordyceps sinensis, antidepressant, mice
Cordyceps sinensis is a fungus of Ascomycetes family closely related to the mushroom. The fungus is parasitic in nature, which grows on an insect larval host (Hepialis armoricanus family Hepialidac). It grows in high-altitude regions of about 11 000– 15 000 ft height, in cold, grassy, alpine meadows of the central Himalayan mountains in India [1]. The fungus has also been found and used extensively in china and Tibet for many medicinal properties. C. sinensis has been known to have so many medicinal properties preventing or curing a number of diseases in the local regions. Local people have been found to use the fungus locally known as Yarsha Gamboo for enhancing stamina, respiratory efficiency, immunomodulation, and treatment of liver, renal, respiratory and cerebrovascular diseases for a very long time. The fungus has also been used for increasing athletic power [1,2]. Because of the high medicinal properties of the C. sinensis, its market price is very high in India as well as in international market. During the last decades, its medicinal effects have been intensively investigated and efforts have been made to culture the fungus in laboratory conditions.
Owing to high medicinal value and high market price of C. sinensis, the present study was aimed to evaluate and compare the neuromuscular activity of the laboratory-cultured mycelia (LCM) as an alternative to wild-harvested C. sinensis in mice.
The natural specimens of C. sinensis (CS) were collected from high altitude areas (13 000 ft) Dharchula-Munsyari region of Pithoragarh, Uttarakhand (India) during May–June 2011. Powder of laboratory-cultured mycelia (LCM) of C. sinensis was obtained from Medicinal Mushroom Laboratory of the Institute. All samples were freeze dried at –72° in a lyophilizer (Model No. 038, NU Labcare, New Delhi) to prepare a fine powder with the help of a mechanical grinder. The samples were stored in an air-tight container at 4° till further use. Both types of powder were freshly suspended in distilled water just before administration to the mice.
Swiss albino mice (20-25 g, age 10-12 weeks) were obtained from the Experimental Animal House of the Institute. They were kept in the polycarbonate plastic cages under standard conditions (22±3°, RH 50-70%, and 12 h/12 h dark/light cycle) for laboratory animals. The animals had free access to chow food and drinking water. The experimental protocol was approved by the Institutional Animal Ethics Committee and animal care was taken as per the guidelines of CPCSEA (Registration No. 1306/c/09/ CPCSEA, Dated 23rd Nov 2009), Government of India.
For locomotor activity, 48 mice of either sex were randomly divided in 8 groups (6 in each) including one control and standard (fluoxetine 20 mg/kg, p.o.). Natural and LCM of C. sinensis were administered at three nearby doses of 100, 300 and 500 mg/kg, orally for 30 days in rest 6 groups [3]. Locomotor activity of the animal using digital photoactometer (M/S Orchid Scientifics, India) was measured by the interceptions in the photobeams because of animal’s movement in the defined arena.
Neuromuscular endurance (motor coordination) of mice was measured by digital Rota rod apparatus (Orchid Scientifics, Pune). The mice capable of remaining on the revolving rod rotating at the speed of 20 rpm for 3 min or more, in three successive trials, were selected for the study and were divided into one control and six test groups with three doses of 100, 300 and 500 mg/kg, orally for each natural and LCM of C. sinensis to evaluate the activity. The fall off time from the Rota rod for each animal was considered as the activity score [4].
The results in the study are expressed as mean±SEM. Statistical analysis of the results was done by using one way analysis of variance followed by Dunnet’s multiple comparison test [5]. The results are considered significant at P values <0.05.
Fig. 1 depicts the effect of natural specimens and laboratory cultured mycelia of C. sinensis (100, 300 and 500 mg/kg, oral), on neuromuscular performance in mice. C. sinensis at 300 and 500 mg/kg significantly increased the time spent by mice on Rota rod revolving at 20 rpm as compared to control group. However, lower dose (100 mg/kg) failed to exhibit significant enhancement in muscular performance in mice. Natural specimens and laboratory cultured mycelia of C. sinensis produced almost comparable effects. The findings of the present study shows that oral administration of both natural and laboratory-cultured C. sinensis for 30 days enhances neuromuscular endurance and have mood elevator activity in mice. C. sinensis has been shown to have improvement in metabolic threshold, antifatigue and antistress activity [6-11]. In the present study we observed the increased performance of mice on Rota rod for significantly more time than control at the dose rate of 300 and 500 mg/kg. This increased performance can be attributed mainly to increased muscular activity or motor coordination and to improved metabolic and ventilatory response to some extent. This effect of C. sinensis may be because of the presence of carbohydrates (45-51% of dry weight) and polysaccharides (210 KD) in the Indian isolate of C. sinensis [12], which has been earlier reported to promote endurance and energy metabolism [10-13]. Our findings are well supported with those of Kumar et al. where they have reported increased skeletal muscle enduring cellular markers by C. sinensis because of the activated skeletal muscle metabolic regulators [3]. Enhanced muscular performance and antifatigue can also be correlated with proper utilization of glucose as C. sinensis has been reported as hypoglycemic agent [14] and increases insulin sensitivity [15]. C. sinensis has also been found to improve exercise performance even in healthy older subjects [11]. In contrary, a number of human studies using trained cyclists have reported the inefficiency of C. sinensis and C. sinensis-based commercial supplements [16,17] in improving muscular performance. However, these studies have been conducted with athletes who attained their maximum metabolic and ventilatory response and the scope of endurance improvement was minimum. Our study also showed almost similar types of results by natural and LCM of C. sinensis, which can be correlated with the findings of Singh et al. who reported minimal genetic variability between in vitro cultured whole mycelia and natural specimens of C. sinensis [18]. One more reason for increased skeletal muscle activity may be the antioxidative property of C. sinensis, as C. sinensis whether natural or in vitro cultured, possesses antioxidative properties [1,2,19].
Fig. 2 depicts the effect of both types (natural and laboratory cultured) of C. sinensis on locomotor activity in mice. Oral administration of laboratory cultured and natural C. sinensis at higher doses (300 and 500 mg/kg, orally) increased locomotor activity significantly as compared to control mice. However, C. sinensis at the lower dose (100 mg/kg, orally) could not increase photoactometer score significantly as compared to control group of mice. Both types of C. sinensis showed almost similar potency to affect the locomotor activity however, the effect was not so potent as with fluoxetine.
Locomotor activity of mice following oral administration of natural and in vitro cultured mycelia of C. sinensis was recorded to evaluate the antidepressant effect or mood elevating effect in terms of increased locomotor activity. Both natural and LCM samples enhanced locomotor activity at 300 and 500 mg/kg significantly as compared to control, however a dose of 100 mg/kg did not show significant effect to enhance the motor activity in mice. Nishizawa has reported that administration of supercritical fluid extract of C. sinensis, shortened immobility times dose dependently in mouse in tail suspension test showing antidepressant action of the fungus as fatigue is closely related to depression [20]. The findings of the present study are also in accordance with Liang et al. who reported the decreased immobility time in force swim test by C. sinensis [21]. Prolonged swimming time by hot water fraction of C. sinensis in mice has also been reported [18], which is indicative of antidepressant and antifatigue effect. Antidepressant effect of C. sinensis has been reported in the diabetic rats [22]. Some authors have reported the antidepressant-like effect of C. sinensis by both noradrenergic and dopaminergic neurotransmissions, but not by serotoninergic neurotransmission [20]. Our study also support the less involvement of serotonin in antidepressant effect as the photoactometer score by C. sinensis is significantly less than fluoxetine, however the possibility of involvement of noradrenaline and dopamine can not be ruled out. Another reason for antidepressant like effect of C. sinensis may also be elicited due to inhibition of monoamine oxidase (MAO), which is involved in catabolism of excitatory neurotransmitters. However, a further investigation is still required to find out the mechanism involved for antidepressant like activity of C. sinensis.
mycelia of C. sinensis was recorded to evaluate the antidepressant effect or mood elevating effect in terms of increased locomotor activity. Both natural and LCM samples enhanced locomotor activity at 300 and 500 mg/kg significantly as compared to control, however a dose of 100 mg/kg did not show significant effect to enhance the motor activity in mice. Nishizawa has reported that administration of supercritical fluid extract of C. sinensis, shortened immobility times dose dependently in mouse in tail suspension test showing antidepressant action of the fungus as fatigue is closely related to depression [20]. The findings of the present study are also in accordance with Liang et al. who reported the decreased immobility time in force swim test by C. sinensis [21]. Prolonged swimming time by hot water fraction of C. sinensis in mice has also been reported [18], which is indicative of antidepressant and antifatigue effect. Antidepressant effect of C. sinensis has been reported in the diabetic rats [22]. Some authors have reported the antidepressant-like effect of C. sinensis by both noradrenergic and dopaminergic neurotransmissions, but not by serotoninergic neurotransmission [20]. Our study also support the less involvement of serotonin in antidepressant effect as the photoactometer score by C. sinensis is significantly less than fluoxetine, however the possibility of involvement of noradrenaline and dopamine can not be ruled out. Another reason for antidepressant like effect of C. sinensis may also be elicited due to inhibition of monoamine oxidase (MAO), which is involved in catabolism of excitatory neurotransmitters. However, a further investigation is still required to find out the mechanism involved for antidepressant like activity of C. sinensis.
In the view of above findings, it can be concluded that natural as well as LCM of C. sinensis have capacity to increase the motor coordination in form of increased muscle endurance or antifatigue like activity and mood elevator or antidepressant like activity as a result of decreased endogenous depression. The neuromuscular effect of LCM of C. sinensis was almost similar to that of natural samples. Hence, in vitro propagated C. sinensis can be used in development of product formulation for improving human neuromuscular activity and quality of life.
Acknowledgements
We thank Mr. M. C. Arya, Scientist ‘F’, Officer In Charge, and Dr. H. K. Pandey, Scientist ‘D’ of Diber Field Station, Pithoragarh for their valuable support and suggestions during the study.
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