Skip to main content

DETERMINATION OF ANTIBACTERIAL, ANTIFUNGAL AND CYTOTOXIC ACTIVITIES OF N-HEXANE, CHLOROFORM AND ETHYL ACETATE EXTRACTS OF MOMORDICA CHARANTIA LEAVES

 

Clinical courses

{ DOWNLOAD AS PDF }

ABOUT AUTHOR:
Israt Jahan Bulbul
Department of Pharmacy,
Southeast University Banani, Dhaka, Bangladesh
israt_jahanb872@yahoo.com

ABSTRACT
A study was conducted to determine the antibacterial and antifungal activitieswith minimum inhibitory concentration and cytotoxic activity of Momordica charantia (Family: Cucurbitaceae) leaves. In our present study, the antimicroial activity of n-hexane, chloroform and ethyl acetate fractions of the plant were investigated against a number of pathogenic Gram-positive (Bacillus megaterium, Bacillus subtilis, Staphylococcus aureus and Sarcina lutea), Gram- negative (Salmonella paratyphi, Salmonella typhi, Vibrio parahaemolyticus, Vibrio mimicus, Escherichia coli, Shigella dysenteriae, Shigella boydii and Pseudomonas aeruginosa) bacteria and three funguses (Candida albicans, Aspergillus niger and Saccharomyces cerevesiae). Here the zones of inhibitions for the test samples (500 µg /disc) werecompared with that of reference standard (30 µg /disc) in determining antimicrobial activity. All the extracts showed significant antibacterial and antifungal activities against all the pathogenic bacteria except A. niger. The highest sensitivity for n-hexane, chloroform and ethyl acetate fractionswas against gram positive bacteria B.cereus. Almost all the gram positive, gram negative bacteria and fungus were inhibited by ethyl acetate extract and showed better activity compared to n-hexane and chloroform extracts. All the three fractions were tested as antifungal against C. albicans and S. cerevesiae. They showed moderate activity against C. albicans whereas a very good activity against S. cerevesiae. But A. niger was not sensitive to the experimental extracts.Minimum inhibitory concentration (MIC) that is the lowest concentration at which the test sample shows its highest activity against microorganisms was tested by serial dilution method. The MIC for n-Hexane and chloroform extracts was against B. cereus (64 µg /ml).  The ethyl acetate extract exhibited antibacterial activity with MIC of 64 µg /ml against S. aureus, S. luteae, S. boydii, S. dysentereae and V. mimicus. The Brine shrimp lethality bioassay method was used to determine the cytotoxic activity and vincristine sulphate was used as positive control. The LC50 values of standard vincristine sulphate, n-hexane, chloroform and ethyl acetate extract were 10.18 µg /ml, 24.71 µg /ml, 19.02 µg /ml and 30.38 µg/ml respectively which indicate the presence of bioactive compounds present in the plant extracts are promisingly cytotoxic.

REFERENCE ID: PHARMATUTOR-ART-2395


PharmaTutor (Print-ISSN: 2394 - 6679; e-ISSN: 2347 - 7881)

Volume 4, Issue 3


Received On: 01/10/2015; Accepted On: 05/10/2015; Published On: 01/03/2016

How to cite this article: Bulbul IJ; Determination of Antibacterial, Antifungal and Cytotoxic activities of n-Hexane, Chloroform and Ethyl Acetate extracts of Momordica charantia leaves; PharmaTutor; 2016; 4(3); 28-33

INTRODUCTION
Momordica charantiais called bitter melon or bitter gourd in English, is a tropical and subtropical vine of the family Cucurbitaceae, widely grown in Asia, Africa, and the Caribbean for its edible fruit, which is among the most bitter of all fruits. In folk medicine, M. charantia has significant role. The fruit and various parts of this plant have demonstrated wide range of medicinal properties in further researches. Bitter melon fruit contains triterpene lycosides, including the characteristic mormordin and charantin. Other triterpene glycosides (the momordicosides), vitamins, including beta carotene, ascorbic acid, niacin, and thiamin, elemental compounds (e.g. iron, iodine, magnesium, sodium, calcium), and fatty acids, including stearic, palmitic, and oleic, are also present. Bitter melon seeds and the pericarp contain the phenolics catechin and epicatechin, gallic, gentisic, and vanillic acids, as well as lutein, lycopene, carotenes, xanthins, momordicosides, and vicine [1] [2].The essential oil obtained from the seeds contains sesquiterepene, phenylpropanoids, and monoterpenes, including nerolidol,apiole, cis-dihydrocarveol and germacrene D [3]. Eight compounds have been isolated from the fruits of M. charantiawere identified as momordicolide (10E)-3-hydroxyl-dodeca-10-en-9-olide,  monordicophenoide A (4-hydroxyl-benzoic acid 4-O-beta-D-apiofuranosyl -O-beta-D-glucopyranoside, dihydrophaseic acid 3-O-beta-D-glucopyranoside , 6,9-dihydroxy-megastigman-4,7-dien-3-one (blumenol, 4), guanosine , adenosine , uracil  and cytosine [4].

Leaves extracts showed the presence of different classes of secondary metabolites as flavonoids, alkaloids and tannins [5].

M. charantia fruit extract possesses the anti-oxidant activity [6]. It prevents alterations in lipid profile and lipogenic enzymes [7], prevents hyperglycemia and hyperinsulinemia [8],prevent carcinogenesis of colon [9].Bitter melon is used experimentally in the treatment of HIV infection [10] and it also inhibits microsomal triglyceride transfer protein gene expression and apoB secretion in HepG2cells [11].

As various parts of M. charantia are of great use in folklore medicine and previous investigations signifies that different parts are therapeutically effective, it may be possible that the leaves have therapeutic effects too. The present study was undertaken for performing different biological screening such as in vitro antibacterial activity, minimum inhibitory concentration and cytotoxic activity of crude extracts of M. charantia leaves.

Materials and Methods

Plant material
The fresh leaves from the plant of M. charantia were collected in the month of January, 2011. This is a familiar plant and widely distributed in all over Bangladesh.

Plant materials extraction and fractionation
The fresh leaf was collected, sun dried for seven days and ground. The dried powder of M. charantialeaf (200 gm) was soaked in 600 ml of ethanol for 7 days and filtered through a cotton plug followed by Whatman filter paper number 1. The concentrated ethanolic extract of leaf was fractionated by the modified Kupchan partitioning method into n-hexane, chloroform and ethyl acetate. The subsequent evaporation of solvents afforded n-hexane (450 mg), chloroform (700 mg) and ethyl acetate (350 mg) from leaf extract.

Antibacterial assay
In our present study, the antibacterial activity of n-hexane, chloroform and ethyl acetate fractions of the plant were investigated against a number of pathogenic Gram-positive and Gram- negative bacteria and three funguses. The microorganisms were collected as pure cultures from the Institute of Nutrition and Food Science (INFS), University of Dhaka, Bangladesh. The sample solution of the material to be tested was prepared by dissolving a definite amount of material in methanol to attain a concentration of 50 mg/ml. 10 μl of such solution was applied on sterile disc (5 mm diameter, filter paper) and allowed to dry off the solvent in an aseptic hood. Thus, such discs contain 500 μg of crude extracts. To compare the activity with standard antibiotics, kanamycin (30 μg/disc) was used.

Minimum Inhibitory Concentration (MIC) measurements:
A current definition of the minimum inhibitory concentration (MIC) is the lowest concentration which resulted in maintenance or reduction of inoculums viability [12]. Serial tube dilution technique [13] [14] was used to determine of MIC of the extracts against four gram-positive and four gram-negative bacteria. The plant extract (0.512 mg) was dissolved in 2 ml distilled water (2 drops tween-80 was added to facilitate dissolution) to obtain stock solution. After preparation of suspensions of test organisms (107 organism per ml), 1 drop of suspension (0.02 ml) was added to each broth dilution. After 18 h incubation at 37°C, the tubes were then examined for the growth. The MIC of the extract was taken as the lowest concentration that showed no growth. Growth was observed in those tubes where the concentration of the extract was below the inhibitory level and the broth medium was observed turbid (cloudy). Distilled water with 2 drops of tween-80 and kanamycin were used as negative and positive control, respectively.

­­­­­­­Cytotoxicity Screening

Brine shrimp Lethality Bioassay
Brine shrimp lethality bioassay [15] [16]was used for probable cytotoxic activity. The eggs of Brine Shrimp (Artemia salina ) was collected from local pet shops and hatchedin a tank at a temperature around 37 ºC with constantoxygen supply. Two days were allowed to hatch and maturethe nauplii. Stock solution of the sample was prepared bydissolving required amount of extract in specific volumeof pure dimethyl sulfoxide (DMSO) to attain concentrations of 5, 10, 20, 40 and 80 mg/ml. With the help of apasteur pipette nauplii were exposed to different concentrationsof the extracts.

Results

Result ofAntimicrobial activity
The results representing antibacterial and antifungal activity of the n-hexane, chloroform and ethyl acetate fraction of M. charantia are presented in Table: 1. Among all the extracts ethyl acetate extract of M. charantia leaves showed very good (average zone 14-20 mm) antimicrobial activity against most of the gram positive and gram negative bacteria and fungus at a concentration of 500µg/disc. In the comparison to reference standard the ethyl acetate extract of M. charantia leaves showed significant antibacterial activity. In the present experiment, we found that the ethyl acetate extract showed comparatively better antimicrobial activity than that of n-hexane and chloroform extracts. The chloroform and the n-hexane extracts were also found as good antimicrobial with an average zone 11-20 and 8-19 mm. The chloroform fraction inhibited most of the organisms that is significant to reference standard. The highest zones of inhibition for n-hexane and chloroform extracts were 19 mm and 20 mm respectively against B. cereus whereas maximum inhibition (20 mm) for ethyl acetate extracts against B. cereus, S. lutea and S. dysenteriae. All the extracts showed antifungal activity and are active against C. albicans and S. cerevesiae but not sensitive to A. niger.

Result of Minimum Inhibitory Concentration
The Minimum inhibitory concentration (MIC) of all the extracts was 64µg /ml against B. cereus. Chloroform extract showed very good activity against S.  luteae where the MIC was 64µg /ml. The ethyl acetate extract showed very good activity against S. aureus, S. luteae, S. boydii, S. dysenteriae and V.  mimicus with MIC value 64 µg/ml. Ethyl acetate extract showed good activity againstS. paratyphi, V.  parahaemolyticus, P.  aeruginosa, S.  cerevisiae and E.  coli. with MIC value 128µg /ml.

Result of Brine Shrimp Lethality Bioassay
The Brine shrimp lethality bioassay method was used to determine the cytotoxic activity and vincristine sulphate was used as positive control. The LC50 values of standard vincristine sulphate, n-hexane, chloroform and ethyl acetate extract were 10.18µg/ml, 24.71 µg/ml, 19.02 µg/ml and 30.38 µg/ml respectively.

Discussion
Finding healing powers in plants is an ancient idea. Clinical microbiologists have two reasons to be interested in the topic of antimicrobial plant extracts. First, it is very likely that these phytochemicals will find their way into the arsenal of antimicrobial drugs. Second, the public is becoming increasingly aware of problems with the over prescription and misuse of traditional antibiotics. Plants have an almost limitless ability to synthesize aromatic substances, most of which are phenols or their oxygen substituted derivatives [17].  Most are secondary metabolites, of which at least 12,000 have been isolated, a number estimated to be less than 10% of the total [18]. In many cases, these substances serve as plant defense mechanisms against predation by microorganisms, insects, and herbivores. Some such phytochemicals include terpenoids and essential Oils, quinones and tannins, flavones, flavonoids, and flavonols, coumarins, alkaloids, lectins and polypeptides and others.

The presence of as flavonoids, alkaloids and tannins [5]confirm its activity as antimicrobials. So, antimicrobial activity of the studied plant M. charantia is probably due to the ability of i) flavones to complex with extracellular and soluble proteins and to complex with bacterial cell walls, more lipophilic flavonoids may also disrupt microbial membranes [19], ii) tannins to inactivate microbial adhesins, enzymes, cell envelope transport proteins [20].

Brine shrimp lethality bioassay is a recent development in the bioassay for bioactive compounds which indicates toxicity as well as a wide range of pharmacological activities (i.e. anticancer, antiviral, insecticidal and pesticidal etc) of the compounds. Bioactive compounds are almost always toxic in high doses. Here, in vivo lethality in a simple zoological organism (Brine Shrimp nauplii) is used as a convenient monitor for screening and fractionation in the discovery of new bioactive natural products. The mortality rate of brine shrimp was found to be increased with increase in concentration of samples and a plot of log of concentration versus percent mortality on the graph produced an approximate linear correlation between them. From this graph the concentration at which 50% mortality (LC50) of the brine shrimp nauplii occurred was determined for most of the samples.  In this assay, the extracts showed positive results indicating that the compounds are biologically active. This experiment revealed that each of the test samples showed different mortality rates at different concentrations.

Table 1: In vitro antimicrobial activity of the extracts of M. charantia (leaves)

Name of the Organism

Type of the Exract

Standard

 

n-Hexane

Chloroform

Ethyl acetate

Kanamycin

(30 µg/disc)

Gram positive

Zone of Inhibition (mm)

 

B. subtilis

B. megaterium

B. cereus

S. aureus

S. Lutea

14

11

15

8

12

14

19

20

20

15

12

18

14

16

20

30

29

32

30

32

Gram negative

 

 

S. paratyphi

V. parahaemolyticus

V. mimicus

S. boydii

S. dysenteriae

E. coli

P. aeruginosa

16

13

15

-

15

17

13

15

17

-

13

15

14

14

20

10

14

18

14

13

18

29

31

30

29

32

30

31

Fungus

 

 

C. albicans

A. niger

S. cerevesiae

9

11

14

-

-

-

16

13

17

29

30

30

(-)=No significant antibacterial activity.

y(n)= n-Hexane, Y(C)= Chloroform, Y(E)= Ethyl acetate, Y(V)= Vincristine sulphate

Figure 1: Determination of LC50 values for standard and crude n-hexane, chloroform and ethyl acetate extracts of M. charantia leaves from linear correlation between logarithms of concentration versus percentage of mortality.

Table 2: The minimum inhibitory concentrations (MIC) of the leaf extract of n-Hexane, chloroform and ethyl acetate of M.  charantia

 

Name of the Organism

Minimum Inhibitory Concentrations (MIC)

 

n-Hexane (µg /ml)

Chloroform (µg /ml)

E. acetate (µg /ml)

Staphylococcus aureus

128

256

64

Bacillus cereus

64

64

64

Sarcina luteae

128

64

64

Salmonella paratyphi

64

256

128

Vibrio parahaemolyticus

-

128

128

Shigella boydii

-

256

64

Shigella dysenteriae

256

128

64

Eshcheria coli

512

128

128

Pseudomonus aeruginosa

256

256

128

Vibrio mimicus

256

128

64

Sacaromyces cereveceae

128

256

128

CONCLUSION
The present study indicates that the n-hexane, chloroform and ethyl acetate extracts of the different parts of M. charantiaexhibited good to excellent antimicrobial activity. The different extracts of leaf of the plant have most potential antimicrobial properties. So the plants may be considered as good sources of natural antimicrobial activity for medicinal uses in various infections. Now the future study of M. charantiawill be directed to explore the bioactive compounds responsible for antibacterial activity. Therefore, further investigation should be necessary for the development of novel lead compound.

REFERENCES
1. Duke J. CRC Handbook of Medicinal Herbs. Boca Raton, FL; CRC Press Inc; 1989; 315-316.
2. Horax R, Hettiarachchy N, Chen P; Extraction, quantification, and antioxidant activities of phenolics from pericarp and seeds of bitter melons (Momordica charantia) harvested at three maturity stages (immature, mature, and ripe); J Agric Food Chem; 2010; 58(7); 4428-4433.
3. Braca A, Siciliano T, D'Arrigo M, Germanò MP; Chemical composition and antimicrobial activity of Momordica charantia seed essential oil; Fitoterapia; 2008; 79(2); 123-125.
4. Li QY, Liang H, Wang B, Zhao YY; Chemical constituents of Momordica charantia L; Yao Xue Xue Bao; 2009; 44(9); 1014-1018
5. José Galberto M. Costa, Eidla M. M. Nascimento, Adriana R. Campos and Fabiola F. G. Rodrigues; Antibacterial activity of Momordica charantia (Curcubitaceae) extracts and fractions; Journal of Basic and Clinical Pharmacy, 2011; 2(1); 45-53.
6. Asli SEMIZ,  Alaattin SEN; Antioxidant and chemoprotective properties of Momordica charantia L. bitter melon fruit extract; African Journal of Biotechnology; 2007; 6(3)273-277.
7. Yadav Umesh CS, Moorthy K, Baquer Najma Z; Combined treatment of sodium orthovanadate and Momordica charantia fruit extract prevents alterations in lipid profile and lipogenic enzymes in alloxan diabetic rats; Molecular and Cellular Biochemistry; 2005; 268(1); 111-120.
8. Vikrant V, Grover JK, Tandon N, Rathi SS, Gupta N; Treatment with extracts of Momordica charantia and Eugenia jambolana prevents hyperglycemia and hyperinsulinemia in fructose fed rats; J Ethnopharmacol; 2001; 76(2); 139-143.
9. Khan SA; Bitter gourd (Momordica charantia): A potential mechanism in anti-carcinogenesis of colon; World Journal of Gastroenterology; 2007; 13(11); 1761-1762.
10. Rebultan SP; Bitter melon therapy: an experimental treatment of HIV infection; AIDS Asia, 1995; 2(4), 6-7.
11. Nerurkar PV, Pearson L, Efird JT, Adeli K, Theriault AG, Nerurkar VR;  Microsomal triglyceride transfer protein gene expression and ApoB secretion are inhibited by bitter melon in HepG2 cells; Journal of Nutrition; 2005; 135(4); 702-706.
12. Carson CF, Hammer KA, Riley TV; Broth micro-dilution method for determination of susceptibility of Escherichia coli and Staphylococcus aureus to the essential oil of Malaleuca alterifolia (Tea tree oil); Microbios; 1995; 82(332); 181-185.
13. Iwaki K, Koya-Miyata S, Kohno K, Ushio S, Fukuda S; Antimicrobial activity of Polygonum tinctorium Lour; Extract against oral pathogenic bacteria; Journal of Natural Medicines; 2006; 60(2); 121-125.
14. Khan A, Rahman M, Islam S; Antibacterial, antifungal and cytotoxic activities of Tuberous Roots of Amorphophallus campanulatus; Turk. J. Biol.; 2007; 31; 167-172.
15. Meyer BN, Ferrigni NR, Putnam JE, Jacobsen LB, Nichols DE, Mclaughlin JL; Brine shrimp; a convenient general bioassay for the active plant constituents; Planta Medicine; 1982; 45; 31-34.
16. Zhao GX, Y.-H. Hui, Rupprecht JK, McLaughlin JL, Wood KV; Additional  bioactive compounds and trilobacin, a novel highly cytotoxic acetogenin, from the bark  of Asimina triloba; Journal of Natural Products; 1992; 55(3); 347-356.
17. T. A. Geissman, Flavonoid compounds, tannins, lignins and related compounds, p. 265. In M. Florkin and E. H. Stotz (ed.), Pyrrole pigments, isoprenoid compounds and phenolic plant constituents, vol. 9. Elsevier, New York, N.Y, 1963.
18. R. E. Schultes, The kingdom of plants, p. 208. In W. A. R. Thomson (ed.), Medicines from the Earth. McGraw-Hill Book Co., New York, N.Y., 1978.
19. H Tsuchiya, M. Sato, T. Miyazaki, S. Fujiwara, S. Tanigaki, M. Ohyama, T. Tanaka, and M. Iinuma; Comparative study on the antibacterial activity of phytochemical flavanones against methicillin-resistant S. aureus; J. Ethnopharmacol; 1996; 50(1); 27-34.
20. C.Ya, S. H. Gaffney, T. H. Lilley, and E. Haslam. Carbohydrate polyphenol complexation, p. 553. In R. W. Hemingway and J. J. Karchesy(ed.), Chemistry and significance of condensed tannins. Plenum Press, New York, N.Y., 1988.

NOW YOU CAN ALSO PUBLISH YOUR ARTICLE ONLINE.

SUBMIT YOUR ARTICLE/PROJECT AT editor-in-chief@pharmatutor.org

FIND OUT MORE ARTICLES AT OUR DATABASE