IN VITRO MICROPROPAGATION OF AJUGA TURKESTANICA (REGEL) BRIQ.: A PATHWAY TO PATHOGEN-FREE SEEDLINGS

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IN VITRO MICROPROPAGATION OF AJUGA TURKESTANICA (REGEL) BRIQ.: A

PATHWAY TO PATHOGEN-FREE SEEDLINGS

Mannabova M.M., Kushiev Kh.Kh., Bakeyev R.

Research Institute Agrobiotechnologies and Biochemistry of Gulistan State University

Email

: mmannabova@gmail.com

ABSTRACT:

In recent years, the application of in vitro techniques has become a cornerstone in

the conservation and propagation of plant biodiversity. This study focuses on the

micropropagation of Ajuga Turkestanica, a medicinal plant species, under in vitro conditions. The

research aimed to identify the optimal nutrient media and growth regulators for the efficient

propagation of pathogen-free seedlings. The results demonstrated that the B5 nutrient medium

supplemented with 0.1 µM BAP (6-Benzylaminopurine) was the most effective for the

proliferation of Ajuga Turkestanica. Additionally, the BDS medium enriched with 5.0 µM BAP

and 2.0 µM NAA (Naphthalene Acetic Acid) showed high efficiency in promoting shoot

regeneration. The study also highlighted the importance of cytokinins, particularly BAP, over

other growth regulators like TDZ (Thidiazuron) and Kinetin in the multiplication phase.

Keywords

: Ajuga Turkestanica, in vitro, micropropagation, callus, MS medium, phytohormones.

INTRODUCTION

The rapid decline in biodiversity due to ecological changes, anthropogenic activities, and

overexploitation of natural resources has necessitated the development of advanced conservation

strategies [1]. Among these, in vitro micropropagation has emerged as a powerful tool for the

preservation and propagation of endangered plant species [2]. This technique not only allows for

the rapid multiplication of plants but also ensures the production of pathogen-free seedlings,

which is crucial for the restoration of natural populations [3].

The genus Ajuga, particularly Ajuga Turkestanica, is of significant interest due to its medicinal

properties. However, the natural populations of this species are under threat due to overharvesting

and habitat destruction [4]. Therefore, the development of efficient in vitro propagation protocols

is essential for its conservation and sustainable utilization [5].

This study aims to explore the morphogenetic responses of Ajuga Turkestanica to various growth

regulators and nutrient media, with the ultimate goal of establishing an optimal protocol for its

micropropagation.

MATERIALS AND METHODS
Plant Material and Sterilization

The study utilized Ajuga Turkestanica explants collected from greenhouse-grown plants. The

explants, consisting of shoot tips and nodal segments, were carefully excised and washed under

running tap water for 30 minutes to remove surface contaminants. For sterilization, the explants

were treated with 70% ethanol for 30 seconds, followed by immersion in a solution of 0.1%

mercuric chloride (HgCl₂) and 0.1% Tween 80 for 30 minutes. After sterilization, the explants

were rinsed three times with sterile distilled water to remove any traces of the sterilizing agents.

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This protocol resulted in a high survival rate of 87-96%, with minimal contamination observed

during the initial culture phase [6].

Nutrient Media and Growth Regulators

The explants were cultured on two primary nutrient media: MS (Murashige and Skoog) [7] and

VM (Van der Meer) [8]. Both media were supplemented with different concentrations of growth

regulators, including BAP (6-Benzylaminopurine), Kinetin, and NAA (Naphthalene Acetic Acid).

The pH of the media was adjusted to 5.8 using 1N NaOH or HCl before autoclaving at 121

0

C for

15 minutes. The media were solidified with 0.8% agar (w/v) and dispensed into sterile culture

vessels.

Experimental Design

The study was designed to evaluate the effects of different growth regulator combinations on the

morphogenetic potential of Ajuga Turkestanica. A total of 10 different media formulations were

prepared, each with varying concentrations of BAP (0.1–5.0 µM) and NAA (0.02–2.0 µM). The

explants were cultured in these media under controlled environmental conditions, with a 16-hour

photoperiod provided by cool-white fluorescent lamps (40 µmol m

-2

s

-1

) and a temperature

maintained at 25±2

0

C. Each treatment consisted of 50 explants, replicated three times to ensure

statistical reliability [9].

Data Collection and Analysis

The regeneration frequency (percentage of explants forming shoots), shoot proliferation (number

of shoots per explant), and callus formation (percentage of explants forming callus) were recorded

over a period of 8 weeks. Data were analyzed using one-way ANOVA, and mean values were

compared using Duncan’s Multiple Range Test (DMRT) at a significance level of p<0.05.

Statistical analyses were performed using SPSS software (version 25.0) [10].

RESULTS

The results of the study are presented in detail, with a focus on the effects of different growth

regulators and nutrient media on the shoot regeneration, callus formation, and rooting of Ajuga

Turkestanica. The findings are supported by tables and figures to provide a clear and thorough

explanation of the outcomes.

Effect of Growth Regulators on Shoot Regeneration

The results indicated that the B5 medium supplemented with 0.1 µM BAP was the most effective

for shoot regeneration, with a regeneration frequency of 56.5% and an average of 5.0 ± 1.5 shoots

per explant (Table 1). The BDS medium enriched with 5.0 µM BAP and 2.0 µM NAA also

showed high efficiency, with a regeneration frequency of 66.2% and an average of 4.0±0.8 shoots

per explant. In contrast, the MS and VM media showed lower regeneration frequencies and fewer

shoots per explant, indicating that the B5 and BDS media were more suitable for the

micropropagation of Ajuga Turkestanica.

Table 1. Effect of Different Growth Regulator Combinations on Shoot Regeneration

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MediumBAP (µM)NAA (µM)Regeneration Frequency (%)Average Shoots per Explant

B5

0.1

0.02

56.5

5.0±1.5

BDS

5.0

2.0

66.2

4.0±0.8

MS

2.0

0.1

49.4

2.9±0.7

VM

2.0

0.1

41.8

2.9±0.5

Callus Formation and Indirect Regeneration

The study also observed callus formation in response to low concentrations of BAP (0.5 µM) and

TDZ (0.5 µM). However, the regeneration frequency from callus was relatively low, with only

28% of the callus-derived shoots developing into viable plantlets (Table 2). This suggests that

direct organogenesis is more efficient for the micropropagation of Ajuga Turkestanica compared

to indirect regeneration via callus.

Table 2. Callus Formation and Indirect Regeneration

Growth RegulatorConcentration (µM)Callus Formation (%)Regeneration Frequency (%)

BAP

0.5

37.0

32.0

TDZ

0.5

38.0

28.0

Rooting and Acclimatization

For rooting, the regenerated shoots were transferred to a hormone-free BDS medium, where they

developed roots within 4-5 weeks. The rooted plantlets were then acclimatized in a greenhouse

environment. The acclimatization process involved transferring the plantlets to a substrate

composed of a mixture of sand and peat (1:1 v/v) under high humidity conditions (80-90%) for

the first two weeks, followed by gradual exposure to ambient conditions. The survival rate of the

acclimatized plantlets was 85%, indicating successful adaptation to ex vitro conditions.

Discussion

The results demonstrate that the B5 medium supplemented with 0.1 µM BAP is highly effective

for shoot regeneration in Ajuga Turkestanica, with a high regeneration frequency and a significant

number of shoots per explant. The BDS medium enriched with 5.0 µM BAP and 2.0 µM NAA

also showed promising results, particularly in terms of regeneration frequency. These findings are

consistent with previous studies that have highlighted the importance of cytokinins, particularly

BAP, in promoting shoot proliferation in in vitro cultures [11, 12].

Callus formation was observed in response to low concentrations of BAP and TDZ, but the

regeneration frequency from callus was relatively low. This suggests that direct organogenesis is a

more efficient pathway for the micropropagation of Ajuga Turkestanica, as it bypasses the callus

phase and directly induces shoot formation from explants. This is in line with studies on other

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medicinal plants, where direct regeneration has been shown to be more reliable and efficient [13,

14].

The successful rooting and acclimatization of the regenerated plantlets further validate the

effectiveness of the in vitro propagation protocol. The high survival rate of

85%

indicates that the

plantlets were well-adapted to ex vitro conditions, which is crucial for the large-scale production

and conservation of Ajuga Turkestanica.

Conclusion

In recent years, the application of in vitro techniques has become a cornerstone in the

conservation and propagation of plant biodiversity. This study focuses on the micropropagation of

Ajuga Turkestanica, a medicinal plant species of significant interest due to its therapeutic

properties, under in vitro conditions. The research aimed to identify the optimal nutrient media

and growth regulators for the efficient propagation of pathogen-free seedlings.

The results demonstrated that the B5 nutrient medium supplemented with 0.1 µM BAP (6-

Benzylaminopurine) was the most effective for shoot proliferation, achieving a regeneration

frequency of 56.5% and producing an average of 5.0 ± 1.5 shoots per explant. Additionally, the

BDS medium enriched with 5.0 µM BAP and 2.0 µM NAA (Naphthalene Acetic Acid) showed

high efficiency in promoting shoot regeneration, with a regeneration frequency of 66.2% and an

average of 4.0±0.8 shoots per explant.

The study also highlighted the importance of cytokinins, particularly BAP, over other growth

regulators like TDZ (Thidiazuron) and Kinetin in the multiplication phase. Callus formation was

observed in response to low concentrations of BAP and TDZ, but the regeneration frequency from

callus was relatively low (28%), indicating that direct organogenesis is a more efficient pathway

for micropropagation.

For rooting, the regenerated shoots were transferred to a hormone-free BDS medium, where they

developed roots within 4-5 weeks. The rooted plantlets were successfully acclimatized in a

greenhouse, with a survival rate of 85%.

This study establishes an efficient protocol for the in vitro micropropagation of Ajuga

Turkestanica, ensuring the rapid production of pathogen-free seedlings and providing a reliable

method for the conservation and sustainable utilization of this valuable medicinal plant.

References

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Benson, E.E. (2000). Special symposium: In vitro plant recalcitrance. Do free radicals

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RESEARCH & DEVELOPMENT

SJIF 2019: 5.222 2020: 5.552 2021: 5.637 2022:5.479 2023:6.563 2024: 7,805

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