Int J Pharm Pharm Sci, Vol 7, Issue 3, 111-113Original Article


STANDARDIZATION OF FRIABLE CALLUS DEVELOPMENT IN CATHARANTHUS ROSEUS (LINN.) G. DON

SAIRAM VEERABATHINI1*, SARANG S1, SHALINI S1, DEEPA SANKAR P1

1Plant Biotechnology Division, School of Bio Sciences and Technology, VIT University, Vellore 632014, Tamil Nadu, India.
Email: svkbiotech@gmail.com

Received: 03 Dec 2014 Revised and Accepted: 22 Jan 2015

ABSTRACT

Objective: The objective of the study was to develop an effective hormonal combination for the maximum growth of callus and development of friable calli using the same medium with reduced concentration of agar.

Methods: The percentage responses of five varied growth hormonal combinations and concentrations, supplemented with Murashige and Skoog (MS)medium were recorded. The effect of casein hydrolysate on callus induction was also studied. The nature of friable calli obtained from best responsive media fortified with 0.7% and 0.6% agar was observed.

Results: The present study revealed that, three media viz., MS + 1.0 mg/L BAP + 1.0 mg/L NAA, MS + 1.5 mg/L 2,4-D + 1.0 mg/L Kin and MS + 1.5 mg/L 2,4-D + 0.5 mg/L BAP, as the best responsive media in the descending order. The effect of casein hydrolysate supplemented along with the above three media revealed MS + 1.0 mg/LBAP + 1.0 mg/L NAA + 1.0 gm/L casein hydrolysate as the best responsive media. Also, the above media supplemented with 0.6% agar was found to be the effective in terms of nature and amount of friable callus obtained.

Conclusion: The results indicated MS + 1.0 mg/L BAP + 1.0 mg/L NAA + 1.0 gm/L casein hydrolysate + 0.6% agar (85% response) as the best media for the growth and development of both callus and friable callus.

Keywords: Callus induction, Friable callus, Catharanthus roseus.

INTRODUCTION

Herbal plants are known to produce a wide range of secondary metabolites, also referred to as natural products [1], bioactive compounds or compatible solutes that are used to cure contagious diseases [2-4]. Despite of their usage for food and shelter, they are also cultured on a large scale to obtain valuable compounds which are used in pharmaceuticals, agrochemicals, flavors, fragrances, colors, biopesticides and food additives [5]. Catharanthus roseus (Linn.) G. Don. is one such ornamental plant, also commonly known as Sadabahar (or) Periwinkle [6]. It is a perennial tropical plant, that belongs to the family Apocynaceae and to the place Madagascar [7]. This herbal plant has always gained the nuclear place in the traditional plant system [8]. It has the ability of producing wide range of indole alkaloids which are known to have anti-cancer [9], anti-dysenteric, anti-septic [10], anti-hypertensive, anti-oxidant, anti-malarial, anti-mitotic, anti-fertility, anti-hypercholesterolemic, anti-diabetic, anti-mutagenic, diuretic, anti-inflammation, anti-fungal, anti-spasmodic, anti-viral and anti-tumour properties [11]. C. roseus produces more than 100 mono-terpenoid indole alkaloids (MIAs) [12-15], such as vinblastine, ajmalicine, serpentine [16] etc. that is found in various sections of the plant. Due to its valuable pharmaceutical properties, C. roseus have been the object of various biotechnological studies [17].

Tissue culture technique has immense advantages in culturing medicinal plants to overproduce secondary metabolites, as a resource for herbal and pharmaceutical industries [18]. Cell suspension cultures have been utilized for deriving such plant metabolites of wide medicinal value. The procedure of standardizing friable calli development becomes a necessary step in various plants to manufacture valuable plant metabolites. Therefore, the present study was undertaken to derive callus and friable calli, by optimizing the growth hormones in combination with MS medium.

MATERIALS AND METHODS

Surface sterilization of explants

The explant was derived from C. roseus plants, identified at VIT University, Vellore, Tamil Nadu, India. The leaves were initially surface sterilized by subjecting under running tap water followed by 0.1% bavistin treatment for 30 min. Then these leaves were subjected to detergent wash using 3 drops of Tween-20 for 15 min. These semi-sterilized leaves were then transferred to a laminar air flow chamber and washed with autoclaved distilled water for 4 times. It was further surface sterilized with 75% ethanol for 3 min, and then with 0.1% HgCl2 for 3 min. Washing with autoclaved distilled water in between the treatments, for 4 times were carried out. The sterilized leaves were then cut into bits of 0.5 cm length (explant) and inoculated in MS media along with varied concentrations of growth hormones.

Culture media

Different growth hormonal concentrations and combinations with MS media supplemented with 3% sucrose were prepared viz., BAP (0.5-2.0 mg/l) + NAA (1.0 mg/l), 2,4-D (1.5–2.0 mg/l) + Kin (0.1-1.0 mg/l), 2,4-D (1.5–2.0 mg/l) + BAP (0.1-0.5 mg/l), Kin (0.5–1.0 mg/l) + NAA (1.0–1.5 mg/l) and Kin (0.5–1.0 mg/l) + BAP (1.0–1.5 mg/l) for callus development. The media was supplemented with 0.8% agar and the pH was adjusted to 5.8 prior to autoclaving at 121ºC under 15 lb inch-2 for 15 min.

Callus initiation

The explants after surface sterilization was inoculated in MS media supplemented with varied growth hormonal combinations as mentioned above (with and without casein hydrolysate) (fig. 1a). The cultures were maintained under dark conditions. The date of initiation of callogenesis (fig. 1b), and percentage of responses of callus were recorded in five replicates (table 1). Based on the percentage responses of the callus, the best responsive MS media was chosen and considered for the further experiments.

Callus culture

Thirty days old callus obtained from best responsive media, were further inoculated in the same MS media supplemented with the same hormonal combinations as that of the parent culture. Uniform weights of callus were used for subculturing. Five subsequent passages were done using the similar media (fig. 1c, 1d, 1e), at 20 days of interval.

Friable callus culture

After five subcultures the callus were further transferred into MS media with reduced agar concentrations (0.7% and 0.6%) to obtain friable callus (fig. 1f). These partially friable calli obtained after 20 days of its inoculation (table 3), was further subcultured into fresh medium. Finally, the amount (dry weight) of friable callus obtained from the second subculture was recorded (table 4).

RESULTS AND DISCUSSION

Effect of growth hormones

MS media fortified separately with different growth hormones in combinations using leaf bits as explants, were examined to determine the optimum growth hormone requirement for callus initiation and multiplication of callus(table 1).

Table 1: Effect of MS medium supplemented with growth hormones on callus initiation in C. roseus

Plant growth hormones (mg/l) Mean days to callus induction Percentage response
BAP + NAA

0.5 +1.0

1.0 + 1.0

2.0 + 1.0

24

20

21

40

70

60
2,4-D + Kin

1.5 + 0.1

1.5 + 1.0

2.0 + 0.5

-

21

-

-

65

-
2,4-D + BAP

1.5 + 0.1

1.5 + 0.5

2.0 + 0.5

-

21

20

-

65.5

40
Kin + NAA

0.5 + 1.0

1.0 + 1.0

1.0 + 1.5

21

24

21

60

50

55
Kin + BAP

0.5 + 1.0

1.0 + 1.0

1.0 + 1.5

24

-

25

40

-

45

The inoculated explants responded partially to the varied growth hormones supplemented along with MS medium at different rates. Based on maximum percentage of responses, three media combinations viz., MS + 1.0 mg/l BAP + 1.0 mg/l NAA, MS + 1.5 mg/l 2,4-D + 1.0 mg/l Kin and MS + 1.5 mg/l 2,4-D + 0.5 mg/l BAP were chosen and considered for further experiments. The maximum percentage of response by a calli was shown in MS + 1.0 mg/l BAP + 1.0 mg/l NAA, after 20 days of its inoculation.

In harmony, Renu Singh et al. (2011) reported that, leaf (explant) inoculated in MS + 3.0 mg/l BAP + 2.0 mg/l NAA subjected to light (13 days to callus induction) and dark (12 days to callus induction) conditions separately, proved to be the best responsive media (92.2 and 90.2% respectively). In contrast, Rukhama Haq et al. (2013) [19], reported that MS + 1.0 mg/l 2,4-D + 1.0 mg/l Kin as the best responsive media (95%). Also, Ashutosh Vermaet al. (2012) and Taha et al. (2008) [20], reported that MS media supplemented with 1.0 mg/l 2,4-D + 0.5 mg/l BA and 1.0 mg/l 2,4-D + 1.0 mg/l Kin respectively, produced the highest mass of callus with leaf as an explant.

Effect of casein hydrolysate

Effect of casein hydrolysate supplemented along with MS media and three best responsive growth hormones obtained, was examined. The nature of the callus produced and days to callus induction were recorded (table 2).

Fig. 1: Development of friable callus
A: leaf bit (explant) inoculation, B: initial growth of callus,
C: third subculture, D: fourth subculture, E: fifth subculture,
F: friable callus

Table 2: Effect of casein hydrolysateon callus initiation

Key component Media composition Mean days to callus induction Nature of the callus (colour) Percentage of responses (%)
With casein hydrolysate (1.0 gm/l)

MS + 1.0 mg l-1 BAP

+ 1.0 mg l-1 NAA

 16 White 85

MS + 1.5 mg l-1 2,4-D

+ 1.0 mg l-1 Kin

 14 White 80

MS + 1.5 mg l-1 2,4-D

+ 0.5 mg l-1 BAP

 18 White 80
Without casein hydrolysate

MS + 1.0 mg l-1 BAP

+ 1.0 mg l-1 NAA

 20 Brown 70

MS + 1.5 mg l-1 2,4-D

+ 1.0 mg l-1 Kin

 21 White 65

MS + 1.5 mg l-1 2,4-D

+ 0.5 mg l-1 BAP

 21 Green 65.5

It was observed that the callus derived were whiter and took lesser days to callus induction in the presence of the casein hydrolysate compared to the callus obtained on the same media without casein hydrolysate. The maximum response by a friable calli was observed in MS media supplemented with 1.0 mg/l BAP + 1.0 mg/l NAA + 1.0 gm/l casein hydrolysate (table 2). The callus obtained from the best responsive media were subcultured upto five passages, after every 20 days.

Table 3: Mass of friable callus obtained from first passage (gm)

Replicates MS + 1.0 mg/L BAP + 1.0 mg/L NAA + 1.0 gm/Lcasein hydrolysate

0.7% agar

0.6% agar

R1

0.11

 0.49

R2

0.10

 0.38

R3

0.11

 0.29

R4

0.15

 0.57

R5

0.08

 0.87

R6

0.12

 0.25

R7

 0.12 0.22

R8

 0.15 0.20

R9

 0.13 0.23

R10

 0.10 0.26

Mean

 0.117 0.376

SD

 0.073 0.204

SE

 0.023 0.064

It was observed that the amount of friable calli derived from the second passage particularly from the media supplemented with 0.6% agar was comparatively more (table 4) and loose.

Table 4: Mass of friable callus obtained from second passage (gm)

Replicates MS + 1.0 mg/L BAP + 1.0 mg/L NAA + 1.0 gm/Lcasein hydrolysate

0.7% agar

0.6% agar

R1

0.16

 0.45

R2

0.15

 0.40

R3

0.13

 0.46

R4

0.19

 0.43

R5

0.19

 0.41

R6

0.13

 0.40

R7

 0.13 0.42

R8

 0.11 0.40

R9

 0.12 0.43

R10

 0.13 0.44

Mean

 0.144 0.424

SD

 0.026 0.02

SE

 0.008 0.006

Mass of friable callus

The friable callus obtained from the best responsive media were taken into consideration. The mass of that particular callus after 20 days of inoculation into a fresh media, was recorded (table 3). Also, it was again transferred onto a same media as that of the parent media. The weight (grams) of the friable callus obtained after 20 days of inoculation were recorded (table 4).

CONCLUSION

In the present investigation of developing the callus and friable callus in Catharanthus roseus, we found that the MS basal media fortified with growth hormones, BAP (1.0 mg/L) and NAA (1.0 mg/L) was the best responsive (70%) media for callogenesis. We have also studied the effect of casein hydrolysate(1.0 gm/L) supplemented along with MS media and the best responsive growth hormones, on callus induction and development. Casein hydrolysate was found to be a positive regulator (85% response) and it induced growth in lesser days. To obtain the friable callus, best responsive media were supplemented along with reduced agar concentrations of 0.7% and 0.6%. Media with 0.6% agar resulted to be the best in terms of the nature and mass of the callus obtained. Finally, we can conclude that the MS + 1.0 mg/L BAP + 1.0 mg/L NAA + 1.0 gm/L casein hydrolysate + 0.6% agar as the best media for the growth and development of both callus and friable callus.

ACKNOWLEDGEMENT

We are immensely thankful to the facilities provided by the management of VIT University, Vellore, India. We also thank Plant Biotechnology Division for providing us with work space.

CONFLICT OF INTERESTS

Declared None

REFERENCES

  1. Ashutosh KV, Singh RR, Seema S. Improved alkaloid content in callus culture of Catharanthus roseus. Bot Serbica 2012;36(2):123-30.
  2. Kiruba S, Mahesh M, Nisha SR, Miller PZ, Jeeva S. Phytochemical analysis of the flower extracts of Rhododendron arboretum Sm. Ssp. Nilagiricum (Zenker) Tagg. Asian Pac J Trop Biomed 2011;284-6.
  3. Tirupathi RG, Suresh BK, Ujwal KJ, Sujana P, Veerabhadr R, Sreedhar AS. Anti-microbial principles of selected remedial plants from southern India. Asian Pac J Trop Biomed 2011;1(4):298-305.
  4. Anpin Raja RD, Jeeva S, Prakash JW, Johnson M, Irudayaraj V. Antibacterial activity of selected ethnomedicinal plants from South India. Asian Pac J Trop Biomed 2011;4(4):375-8.
  5. Mathew R, Sankar PD. Plant cell culture technology and its entrée into the world of Ocimum. Int J Pharm Pharm Sci 2013;5 Suppl 2:6-13.
  6. Soon HT, Chung YL, Hazrina H, Aditya A, Mohammadjavad P, Won FW, et al. Antidiabetic and antioxidant properties of alkaloids from Catharanthus roseus (L.) G. Don. Mol 2013;18:9770-84.
  7. Jaleel CA, Gopi R, Manivannan P, Sankar B, Kishorekumar A, Panneerselvam R. Antioxidant potentials and ajmalicine accumulation in Catharanthus roseus after treatment with giberellic acid. Colloids Surf B 2007;60:195-200.
  8. Renu S, Pushpa K, Kanta R. Rapid micropropagation and callus induction of Catharanthus roseusin vitro using different explants. World J Agric Sci 2011;7(6):699-704.
  9. Bakrudeen AAA, Subha Shanthi G, Gouthaman T, Kavitha MS, Rao MV. In vitro micropropagation of Catharanthus roseus–An anticancer medicinal plant. Acta Bot Hung 2011;53(1-2):197-209.
  10. Jitendra M, Deeksha U, Priyanka P, Rukhshar A, Sunil R, Shalini T. Multiple shoots regeneration of (anti-cancer plant) Catharanthus roseus–An important medicinal plant. Am J Pharm Tech Res 2013;3;1.
  11. Mohammed I, Syeda Sughra Mehjabeen, Mangamoori LN. Pharmacological evaluation of Catharanthus roseus. Int J Pharm Appl 2011;2(3):165-73.
  12. Rupesh KR, Naresh KS, Vandana S. Effect of plant growth regulators on micropropagation of Catharanthus roseus. Int J Adv Biotechnol Res 2013;4(1):123-30.
  13. Van der HR, Jacobs DI, Snoeijer W, Hallard D, Verpoorte R. The Catharanthus roseus alkaloids: pharmacognosy and biotechnology (a review). Curr Med Chem 2004;11:607-28.
  14. Magnotta M, Murata J, Chen J, De LV. Identification of a low vindoline accumulating cultivar of Catharanthus roseus (L.) G. Don. by alkaloid and enzymatic profiling. Phytochem 2006;67:1758-64.
  15. Jaleel CA, Gopi R, Sankar B, Manivannan P, Kishorekumar A, Sridharan R, et al. Alterations in germination, seedling vigour, lipid peroxidation and proline metabolism in Catharanthus roseus seedlings under salt stress. South Afr J Bot 2007;73:190-5.
  16. Akira I, Hideki A, Masaru OT, Hideo T. Development of a novel system for producing ajmalicine and serpentine using direct culture of leaves in Catharanthus roseus intact plant. J Biosci Bioeng 2005;99(3):208-15.
  17. Agnieszka P, Miroslawa F, Barbara L. Catharanthus roseus: micropropagation and in vitro techniques. Phytochem Rev 2007;6:459-73.
  18. Sidhu Y. In vitro micropropagation of medicinal plants by tissue culture. Plymouth Student Sci 2010;4(1):432-49.
  19. Rukhama H, Shagufta N, Farah A, Farkhanda M. Comparison of in vitro response of micropropagation and callogenesis of medicinal plant, Vinca rosea L. J Agric Res 2013;51(1):9-17.
  20. Taha HS, El-Bahr MK, El-Nasr MMS. In vitro studies on Egyptian Catharanthus roseus (L.) G. Don: Calli production, direct shootlets regeneration and alkaloids determination. J Appl Sci Res 2008;4(8):1017-22.