Evaluation of Mosquito Larvicidal Activities of Seed Coat Extract of Cassia sophera L.  

Mousumi Kundu , Anjali Rawani , Goutam Chandra
Mosquito and microbiology Research Units, Department of Zoology, The University of Burdwan, West Bengal, India
Author    Correspondence author
Journal of Mosquito Research, 2013, Vol. 3, No. 11   doi: 10.5376/jmr.2013.03.0011
Received: 11 Apr., 2013    Accepted: 18 Apr., 2013    Published: 10 Jul., 2013
© 2013 BioPublisher Publishing Platform
This is an open access article published under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Preferred citation for this article:

Kundu et al., 2013, Evaluation of Mosquito Larvicidal Activities of Seed Coat Extract of Cassia sophera L., Journal of Mosquito Research, Vol.3, No.11 76-81 (doi: 10.5376/jmr.2013.03.0011)

Abstract

In the present study an attempt was made to analyze the larvicidal activity of crude and ethyl acetate extracts of matured seed coat of Cassia sophera against Culex quinquefaciatus. Crude and ethyl acetate extracts of matured seed coat of Cassia sophera was tested against Culex quinquefaciatus. The lethal concentration was determined and the appropriate lethal concentrations at 24 h for ethyl acetate extract was also studied on non target organisms such as Daphnia sp., Diplonychus annulatum (predatory water-bug) and Chironomus circumdatus larvae (insect). Phytochemical analysis of the crude extract of matured seed coat of Cassia sophera was also done. All the graded concentration (0.6%, 0.7%, 0.8%, 0.9%, 1%) showed significant (p<0.05) larval mortality and result of regression equation revealed that mortality rates were positively correlated with concentrations of extracts. LC50 and LC90 values were calculated at different time intervals, and the lowest values were obtained at 72 h for first instar larvae. In ethyl acetate solvent extract the mortality rate was higher at 520 ppm against Culex quinquefaciatus than the other doses. There was no mortality of non-target organism within 72 h of post exposure to LC50 concentration at 24 h of both crude and solvent extracts under the laboratory condition. The result of preliminary qualitative phytochemical analysis of the seed coat revealed the presence of some secondary metabolite such as saponin, alkaloid and cardiac glycosides. The results support that the tested plant extract can be used for control of larval form of Culex quinquefaciatus.

Keywords
Cassia sophera; Culex quinquefasciatus; Mosquito larvae; Biocontrol

Introduction
Mosquitoes are the most nuisance creature of the nature that causes the transmission of mosquito borne diseases such as malaria, filaria, dengue fever, yellow fever, Japanese encephalitis by some major vectors viz. Anopheles stephensi, Culex quinquefasciatus, Aedes albopictus and Culex vishnui group (James, 1992; Gubler, 1998). The biting of mosquitoes also causes the skin allergy, the biting area becomes inflated and irritation persists (Peng et al., 1999). Culex quinquefasciatus is a vector of lymphatic filariasis. In tropical countries the lymphatic filariasis is widely distributed infecting 120 million people world wide and common chronic manifestation occur in about 44 million people (Ottesen et al., 1997). Previously mosquito borne diseases were controlled by application of chemical insecticides. For this purpose many chemical insecticides were developed and applied in field with significant success. But the development of resistance, non selective mode of action and harmful to another organisms of the environment are the major negative aspect of chemical insecticides. It may also cause the toxicity to non-target organisms and environment. These developments require efforts to prepare alternative insecticidal agents with high mosquito control activity that cause little or no harmful effect to human health and environment. The plant based herbal insecticides are found to more efficient, safe and best substitute for chemical insecticides (Ghosh, 2012; Chowdhury et al., 2008; Rawani et al., 2009; Rawani et al., 2010; Banerjee et al., 2011). Natural products of plant origin are safe to use than the synthetic insecticides (Kishore et al., 2011). Therefore biological and ecofriendly natural resources are broad search area for the control of vector of medical importance (Singha et al., 2012; Chowdhury, 2009).

Cassia sophera L. (Caesalpiniaceae), a medicinal plant commonly known as Kasaundi, is a shrub of 3 m in height. It is glabrous and having compound leaves with 8~12 paired acute and tapering leaflets; rachis with single gland at the base. It has carymbose racemes inflorescence with yellow flower. The plant is found in most tropical countries. Respiratory disorders medicines are prepared from root bark which is used by ancient Indian physicians. It is widely used as folk medicine for the treatment of many diseases like resolvent, ulcer, asthma, purgative, digestive, diaphoretic (Mostafa et al., 2007; Nagore et al., 2001; Nagore, 2009). In ethno botanical literature, it is mentioned to be effective in the treatment of inflammation, liver damage, asthma, acute bronchitis, cough, diabetes and convulsions of children (Nagore et al., 2010; Suhael et al., 2008; Attiqur et al., 2008).

The purpose of present study was made to evaluate the efficacy of crude and solvent extract of matured seed coat of C. sophera against the larvae of filarial vector Cx. quinquefasciatus as well as some non-target organisms. A preliminary phytochemical analysis was also done to get some idea about the active principle.

1 Result
Present study revealed highest mortality at 1% concentration of crude extract, tested against all larval instars and significantly (p<0.05) higher than 0.6%, 0.7%, 0.8% and 0.9% at 24 h, 48 h and 72 h of exposures (Table 1). Results of three-way factorial ANOVA were presented in Table 2. The result of regression analysis of crude extract of seed coat extract of C. sophera showed the positive correlation between mortality and exposed concentration with a regression coefficient value (R) values between 0.34 and 0.71. The result of probit analysis (Finney, 1982) showed the lowest value of LC50 and LC90 at 72 hours of exposure for the 1st instar larvae followed by 2nd, 3rd and 4th instar larvae (Table 3). The mortality of 1st, 2nd, 3rd and 4th instar larval forms with ethyl acetate is presented in Table 4. The result of preliminary qualitative phytochemical analysis of tested plant crude extract revealed the presence of some secondary metabolite which may be an active ingredient for larvicidal activity (Table 5). There is no any adverse effect on non target organism after 72 hours of exposure of respective LC50 values at 24 h.
 

 

Table 1 Mean larval mortality of larvae of Cx. quinquefaciatus mosquitoes at different concentration of crude extracts of seed coats of C. sophera (mean of three experiments)

 

 

Table 2 Completely randomized three-way factorial ANOVA using different concentrations, period of exposure and different instar as variables

 

 

Table 3 Log probit analysis and regression analysis of larvicidal activity of crude extracts of seed coats of C. sophera against all instar larvae of Cx. quinquefasciatus

  

 

Table 4 Result of larval mortality of different concentration of ethyl acetate solvent extract of seed coat of C. sophera on all instar of Cx. quinquefasciatus

 

 

Table 5 Result of qualitative phytochemical analysis of the crude extract of the tested plant


2 Discussion
The transmission of mosquito-borne diseases can be interrupted by the potential insecticides of herbal origin at the individual as well as at the community level (Campbell et al., 1993). Recently the natural insecticides of plant origin have been given importance due to their ecofriendly nature and biodegradability as a substitute of synthetic insecticides for the control of vectors of public health importance. Different types of phytochemical of plant either from the whole part or from the specific parts come out with solvent during chemical extraction depending on the polarity of the solvent (Rawani et al., 2012; Chowdhury et al., 2007). These phytochemical generally act as a toxicant for adult, pupa as well as larval form of mosquitoes, while some interfere with the growth (growth inhibitory) and reproduction (ovicide deterrent). The present study evaluate biocontrol efficacy of crude extract and ethyl acetate extract of seed coat of C. sophera against Cx. quinquefasciatus. Highest mortality was recorded in 1% concentration of crude extract against 1st instar larvae. The ethyl acetate extract showed 100% mortality at 520 ppm against 1st instar larvae after 24 h. The phytochemical analysis of crude extract of seed coat of C. sophera indicates the presence of some secondary metabolite which either in single form or in combination with other responsible for larval death. There is no any abnormal behaviour of non-target organisms when they exposed to LC50 value so it is safe to use in natural condition. Some other authors also reported the efficacy of ethyl acetate extract of plant parts against mosquito larvae. Senthil Nathan et al. (2008) reported the activity of ethyl acetate extract of the leaves of Dysoxylum malabaricum against the larvae of Anopheles stephensi. Highest mortality occurred in 4th instar larvae. Matasyoh et al (2008) reported the efficacy of the ethyl acetate extract of leaves of Aloe turkanensis against Anopheles gambiae where 100% mortality occurred at a concentration of 0.2 mg/L with a LC50 value of 0.11 mg/mL. The ethyl acetate extract of leaves of Ocimum sanctum produced significant mortality against Aedes aegypti and Cx. quinquefasciatus, with LC50 values of 425.94 ppm and 592.60 ppm, respectively (Anees, 2008). Rawani et al. (2010) studied on the ethyl acetate solvent extract of Solanum nigrum showed its highest mortality (100%) against Culex quinquefaciatus at 50 ppm dose having LC50 value 17.04 ppm after 24 h of exposure period.

In conclusion, crude and ethyl acetate extracts of C. sophera can be effectively used as a potent mosquito larvicide. Furthermore there is more investigation necessitates to identify the active ingredient and their mode of action and field application which become establishes the C. sophera as a new insecticide in a mosquitoes control program.

3 Material and Method
3.1 Plant material

Fresh and matured seeds of C. sophera were harvested randomly during April~June, 2011, from plants growing at the outskirts of Burdwan (23°16'N, 87°54'E). Initially collected seeds were washed with distilled water and soaked on paper towel.

3.2 Collection of larvae

Mosquito larvae of the species Cx. quinquefasciatus used during the present piece of work were taken from an established mosquito colony of Mosquito Research Unit, Department of Zoology, Burdwan University, maintained at (27±1)℃ temp and 85% RH.

3.3 Preparation of crude extracts
Seed coats were crushed with a mechanical blender and the juice was filtered by Whatman no-1 filter paper. The filtrate was used as stock solution (100% concentration) for further bioassay experiment.

3.4. Preparation of solvent extracts
Dried seed coats (250 g) were put in a Soxhlet apparatus and the plant extract was prepared using ethyl acetate as solvent (extraction period 72 hour and the temperature was < 40℃). The extract was collected in a separate beaker.

3.5 Larvicidal bioassay
According to world health organization standard protocols (WHO, 1981), the larvicidal bioassay with suitable modification was done. Each of the previously made concentration of crude extract was transferred into a sterilized glass petridishes (9 cm diameter, 150 mm capacity). Twenty larvae of each larval instar (1st, 2nd, 3rd, and 4th) of Cx. quinquefasciatus were separately transferred into different petridishes containing appropriate concentration. Larval food (20 mg dried yeast powder) was added in each Petridish. Mortality rates were recorded at 24 hr, 48 hr and 72 hr of post exposure. Dead larvae were recognized when they failed to move after probing with a needle in the siphon or cervical region. The experiments were repeated three times on three different days and maintained at 25~30℃ and 80%~90% relative humidity.

3.6 Effect on non-target organisms
Effect of crude and ethyl acetate extracts were tested against non-target organisms like Daphnia sp., Diplonychus annulatum (predatory water-bug) and Chironomus circumdatus larvae (insect). The predators were exposed to half lethal concentrations of crude and solvent extracts at 24 h to observe the mortality and other abnormalities such as sluggishness and reduced swimming activity up to 72 h of exposure.

3.7 Phytochemical analysis of the plant extracts
Phytochemical analysis of the crude extract of seed coat of C. sophera was carried out according to the methodologies of Harbone (1984) and Stahl (1989). The phytochemicals included under study were saponins, terpenoids, alkaloid, steroids, tannin, flavonoids, cardiac glycosides and free glycoside bound anthraquinones.

3.8 Statistical analysis

The percentage mortality (%M) was corrected using Abbott’s formula (1925). Statistical analysis included the probit analysis (calculating LC50 and LC90 values), regression equations (Y=mortality; X = concentrations) and regression coefficient values. ANOVA was carried out to justify the significance between different variables such as different concentrations, different instars, hours and mortality rate.

Acknowledgments
The authors acknowledge with thanks the help of Dr. Ambarish Mukherjee, Professor of Botany, The University of Burdwan, for identification of the plant. The financial support provided by the DST, New Delhi, India (D.O. NO.SR/ SO/HS/84/2007 dated 08/02/08) is also acknowledged.

References
Abott W.S., 1925, A method of computing the effectiveness of an insecticide, J. Econ. Enotomol., 18(2): 265-267

Anees A.M., 2008, Larvicidal activity of Ocimum sanctum Linn. (Labiatae) against Aedes aegypti (L.) and Culex quinquefasciatus (Say), Parasitol. Res., 103(6): 1451-1453
http://dx.doi.org/10.1007/s00436-008-0991-7 PMid:18704496

Attiqur R., Rahman M.M., Sheik M.I., Shadli S.M., and Alam M.F., 2008, Free radical scavenging activity and phenolics content of Cassia sophera L., Afr. J. Biotech., 7(10): 1591-1593

Banerjee S., Singha S., Laskar S. and Chandra G., 2011, Efficacy of Limonia acidissima L. (Rutaceae) leaf extract on larval immatures of Culex quinquefasciatus Say 1823, Asian Pac. J. Trop. Med., 4(9): 711-717
http://dx.doi.org/10.1016/S1995-7645(11)60179-X

Campbell F.L., Sullivan W.W. and Smith L.N., 1993, The relative toxicity of nicotine, nabasine, methylanaba sine and lupinine for Culicine mosquito larvae, J. Econo. Entomol., 26: 505-509

Chowdhury N., Laskar S. and Chandra G., 2008, Mosquito larvicidal and antimicrobial activity of protein of Solanum villosum leaves, BMC. Complement. Alternat. Med., 8: 62
http://dx.doi.org/10.1186/1472-6882-8-62 PMid:19061512 PMCid:2642758

Chowdhury N., Chatterjee S.K., Laskar S., and Chandra G., 2009, Larvicidal activity of Solanum villosum Mill (Solanaceae: Solanales) leaves to Anopheles subpictus Grassi (Diptera: Culicidae) with effect on non-target Chironomus circumdatus Kieffer (Diptera: Chironomidae). Journal of Pest Science, 82: 13-18
http://dx.doi.org/10.1007/s10340-008-0213-1 
 
Chowdhury N., Bhattacharjee I., Laskar S., and Chandra G., 2007, Efficacy of Solanum villosum Mill. (Solanaceae: Solanales) as biocontrol agent against fourth instar larvae of Culex quinquefasciatus Say, Turkish J. Zool., 31(4): 365-370

Finney D.J., 1982, Probit analysis, Cambridge University Press, Cambridge XV., pp.333

Ghosh A., Chowdhury N., Chandra G., 2012, Plant extracts as potential mosquito larvicide, Indian J. Med. Res, 135: 581-598
PMid:22771587 PMCid:3401688

Gubler D.J., 1998, Dengue and Dengue Hemorrhagic Fever, Clin. Microbio. Rev., 11(3): 480-496
PMid:9665979 PMCid:88892

Harborne J.B., 1984, Phytochemical methods. A guide to modern techniques of plant analysis, Chapman and Hall, London, pp.49-188
http://dx.doi.org/10.1007/978-94-009-5570-7 
 
James A.A., 1992, Mosquito molecular genetics: the hands that feed bite back, Sci., 257: 37-38
http://dx.doi.org/10.1126/science.1352413 
 
Kishore N., Mishra B.B., Tiwari V.K. and Tripathi V., 2011, A review on natural products with mosquitosidal potentials, In: Tiwari VK, editor, Opportunity, Challenge and Scope of Natural Products in Medicinal Chemistry, Kerala: Research Signpost, pp.335-65

Matasyoh J.C., Wathuta E.M., Kairuki S,T,, Chepkorir R, and Kavulani J., 2008, Aloe plant extracts as alternative larvicides for mosquito control, Afr. J. Biotech., 7(7): 912-915

Mostafa M., Momtaz A., Ismet A.J. and Choudhury J.U., 2007, Composition of oil from the seeds of Cassia sophera Linn., Bangladesh J. Sci. Ind. Res., 42(1): 75-78
http://dx.doi.org/10.3329/bjsir.v42i1.358 
 
Nagore D.H., Ghosh V.K. and Patil M.J., 2009, Evaluation of antiasthmatic activity of Cassia sophera Linn, Phcog. Mag., 5(19): 109-118

Nagore D.H., 2009, Determination of phenolic content of Cassia sophera Linn. and the potential antiulcer activity in experimentally induced ulceration, J. Comp. Intigr. Med., 6(1):35: 1-20

Nagore D.H., Ghosh V.K., Patil M.J.and Wahil A.M., 2010, In vitro antioxidant and in vivo anti-inflammatory activity of Cassia sophera Linn, Int. J. Pharma. Pharmaceu. Sci., 2(1): 113-121

Ottesen E.A., Duke B.O., Karam M., and Behbehani K., 1997, Strategies and tools for the control/elimination of lymphatic filariasis, Bull. WHO., 75(6): 491-503
PMid:9509621 PMCid:2487030

Peng Z., Yang J., Wang H., and Simons F.E., 1999, Production and characterization of monoclonal antibodies to two new mosquito Aedes aegypti salivary proteins, Insect. Biochem. Mol. Biol., 29(10): 909-914
http://dx.doi.org/10.1016/S0965-1748(99)00066-1  

Rawani A., Haldar K.M., Ghosh A., and Chandra G., 2009, Larvicidal activities of three plants against filarial vector Culex quinquefasciatus Say (Diptera: Culicidae), Parasitol. Res., 105(5): 1411-1417
http://dx.doi.org/10.1007/s00436-009-1573-z PMid:19644705

Rawani A., Ghosh A., and Chandra G., 2010, Mosquito larvicidal activities of Solanum nigrum L. leaf extract against Culex quinquefasciatus Say, Parasitol. Res., 107(5): 1235-1240
http://dx.doi.org/10.1007/s00436-010-1993-9 PMid:20668877

Rawani A., Ghosh A., Laskar S., and Chandra G., 2012, Aliphatic amide from seeds of Carica papaya as mosquito larvicide, pupicide, adulticide, repellent and smoke toxicant, Journal of Mosquito Research, 2(2): 8-14

Senthil N.S., Hisham A. and Jayakumar G., 2008, Larvicidai and growth inhibition of the malaria vector Anopheles stephensi by triterpenes from Dysoxylum malabaricum and Dysoxylum beddomei, Fitoterapia., 79(2): 106-111
http://dx.doi.org/10.1016/j.fitote.2007.07.013 PMid:17869452

Singha S., Adhikari U., Ghosh A., Chandra G., 2012, Mosquito larvicidal potentiality of Holoptelea integrifolia leaf extract against Japanese encephalitis vector, Culex vishuni group, Journal of Mosquito Research, 2(4): 25-31

Stahl E., 1989, Thin layer chromatography-a laboratory handbook, 2nd edn. Springer; Berlin

Suhael A., Bhosale K.H., Venkat R.N., Gouda S.T. and Shalan M.D., 2008, Study on hepatoprotective activity of leaf extract of cassia sophera Linn. in rats, Ind. J. Pharma., 40(2): s73

WHO, 1981, Instructions for determining the susceptibility or resistance of mosquito larvae to insecticides, WHO/VBC., 81.807
 

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