Development of Randomly Amplified Polymorphic DNA Based SCAR Marker for Identification of Ipomoea mauritiana Jacq (Convolvulaceae)

Vidari is an Ayurvedic herbal drug used as aphrodisiac, galactagogue and is also used in the preparation of Chyavanaprash. Tubers of Ipomoea mauritiana Jacq. (Convolvulaceae), Pueraria tuberosa (Roxb. ex Willd.) DC (Fabaceae), Adenia hondala (Gaertn.) de Wilde (Passifloraceae) and pith of Cycas circinalis L. (Cycadaceae) are all traded in the name of Vidari, creating issues of botanical authenticity of the Ayurvedic raw drug. DNA-based markers have been developed to distinguish I. mauritiana from the other Vidari candidates. A putative 600-bp polymorphic sequence, specific to I. mauritiana was identified using randomly amplified polymorphic DNA (RAPD) technique. Furthermore, sequence characterized amplified region (SCAR) primers (IM1F and IM1R) were designed from the unique RAPD amplicon. The SCAR primers produced a specific 323-bp amplicon in authentic I. mauritiana and not in the allied species.


Introduction
Vidari is one of the popular plant drugs of Ayurveda and is a component of many popular and highly traded Ayurvedic formulations like Chyavanaprash, an ancient Indian dietary supplement. The Ayurvedic Pharmacopoeia of India correlates "Vidari" to tubers of Pueraria tuberosa (Roxb. ex Willd.) DC (Fabaceae) and Ipomoea mauritiana Jacq. (Convolvulaceae) as "Kshiravidari" [1]. However, a recent report by Venkatasubramanian et al. [2] indicates that as per Ayurvedic descriptions they both have similar properties and can be substituted by each other. Several herbal medicine manufacturing units also use the giant potato or I. mauritiana (Syn. I. paniculata or I. digitata) as Vidari instead of P. tuberosa. Vidari is useful as aphrodisiac, cardiotonic, demulcent, diuretic, refrigerant and galactogogue [3]. It is also used in emaciation, enteric fever and spermatorrhea [4]. The annual trade volume of Vidari is ∼500-1000 Metric Tonnes [5].
Ipomoea mauritiana is a branched perennial climber with large tuberous tap roots and glabrous stems and branches; leaves palmately 5-7 lobed; flowers purple, in pedunculate corymbose axillary panicles; fruits ovoid, fourcelled and four-valved capsules, surrounded by enlarged fleshy sepals, seed clothed with many long tawny cottony hairs. The root tubers exude milky, sticky, latex and exhibits annual rings when cut. This species is widely naturalized in tropical parts of the world [6]. Taraxerol, taraxerol acetate, umbelliferone, β-sitosterol, scopoletin and 7-O-βd-glycopyranosyl scopoletin (Scopolin) have been isolated from the methanol extract of the tubers [7]. The roots are used to increase appetite, as a galactagogue, in rejuvenative medicine, as a stimulant, carminative and tonic [8]. Alcohol extract of tubers is stimulant as well as depressant, and has convalescent effect on central nervous system [9,10].
Apart from tubers of P. tuberosa and I. mauritiana, tubers of Adenia hondala (Gaertn.) de Wilde (Passifloraceae) and the pith of Cycas circinalis L. (Cycadaceae) are also traded in the name of Vidari [5]. The Ayurvedic Pharmacopoeia of India stipulates macro-microscopic evaluation and chemical profiling of the botanical materials for quality control and standardization [1]. Use of macro, micro and chemical techniques for authentication has its advantages and disadvantages [11], while molecular markers, once standardized is fool-proof, easy and objective [12].
Molecular genetic tools like barcoding, random amplified polymorphic DNA (RAPD) and sequence characterized amplified region (SCAR) markers are reliable methods for quality control of herbal materials. Fingerprints obtained by RAPD can be employed for identification of raw drug at the molecular level [13], however since it is difficult to reproduce these fingerprints they are preferentially converted to SCAR markers. Molecular marker technology proves to be valuable tool not only for genotyping of medicinal plants but also for detecting adulterations and substitutions in herbal medicines [14][15][16][17].
In our study, we have developed RAPD profile of I. mauritiana, P. tuberosa, A. hondala and C. circinalis. Subsequently, a unique DNA sequence identified from the RAPD profile of I. mauritiana was used to develop a speciesspecific SCAR marker. This marker is useful to distinguish I. mauritiana from its allied species traded as Vidari.  Table 1.

DNA Extraction.
Dried raw plant materials were chopped into small pieces and powdered using liquid nitrogen in mortar and pestle. Samples were later homogenized using CTAB extraction buffer and processed as described in the protocol of Milligan [18]. The extracted DNA was treated with 5 μL of RNase A (10 mg/mL) to remove any contaminating RNA. Purity and yield of DNA were checked using UV Spectrophotometer (UV Pharmaspec 1700, Shimadzu, Tokyo, Japan) by calculating the A 260 /A 280 [19].

RAPD Reaction.
The PCR was performed by adding 25 ng of plant DNA, 2 mM dNTP mix, 30 pM of primer,

DNA Extraction and RAPD.
High molecular weight genomic DNA was isolated from the fresh as well as dried plant samples. The DNA extraction procedure yielded 400-600 ng of DNA per 100 mg of tissue. An absorbance (A 260 /A 280 ) ratio of 1.6-1.8 indicated insignificant levels of contaminating proteins and polysaccharides. All the 40 random decamer primers used for screening, produced distinct, reproducible fingerprint of I. mauritiana, P. tuberosa, C. circinalis and A. hondala. OPA 18 consistently amplified an intense 600-bp band that was unique to I. mauritiana samples and invariant with all the three accessions of this species tested (Figure 1). This 600-bp amplicon was not observed in the other three species under study. into pDRIVE cloning vector and transformed into Qiagen EZ competent cells. The selected white colonies contained the required recombinant construct as was confirmed by reamplification with OPA18. The recombinant construct was sequenced using universal sequencing primers SP6 and T7. The sequencing reaction yielded a 601-bp stretch with the purified band from I. mauritiana (A 371; C 211; G 212; T 323) (Figure 2).

Validation of SCAR Primers.
The designed SCAR primer pair (IM1F and IM1R; Table 2) was used to amplify the genomic DNA from I. mauritiana, C. circinalis, A. hondala and P. tuberosa. A single, distinct and brightly resolved band of 323 bp was obtained only with the accessions of I. mauritiana, while no amplification product was obtained with P. tuberosa, C. circinalis and A. hondala (Figure 3). Reduction of the annealing temperatures did not generate any fragment other than the SCAR, confirming the specificity of the SCAR primer for I. mauritiana.

Discussion
Herbal medicine has been enjoying renaissance among the customers throughout the world. Use of indigenous drugs from plant origin forms a major part of complementary and alternative medicine/traditional medicine (CAM/TM). One of the impediments in the acceptance of herbal formulations is the lack of standardization and quality control profiles. Due to the complex nature and inherent variability of the chemical constituents of plant-based drugs, it is difficult to establish quality control standards. Adulteration of market samples remains a major problem in domestic and export markets due to confusing nomenclature and lack of botanical identification of traded raw drugs [20,21]. Active chemical composition of the herbal formulation depends on several factors including the use of exact species [22]. According to World Health Organization general guidelines for methodologies on research and evaluation of TMs, first step in assuring quality, safety and efficacy of TMs is correct identification [23]. Panax (ginseng) is a representative genus of medicinal herbs which was subjected to several methods of DNA  analysis. The methods, applied by several research groups, included PCR-RFLP, AFLP, RAPD, SSR, sequencing of rDNA-ITS region and DNA barcoding. This is an example of how accurate methods for authenticating medicinal plants are necessary to modernize and standardize herbal medicine [24,25].
RAPD is rapid, simple and can be performed even in the absence of prior genetic information of the plant. The fingerprint patterns obtained are consistent irrespective of physical form, age or agroclimatic source [26].
Many technical disadvantages associated with RAPD have, however, raised questions on its fidelity as a genetic marker technique and prevented its widespread use in recent years. The reproducibility of RAPD is affected by DNA quality, primer and template concentration, different thermocyclers and even different sources of DNA polymerase [15]. Therefore, subsequent conversion of RAPD to SCAR markers, by developing longer, hence more specific primers from RAPD sequences, has significantly improved the reproducibility and reliability of PCR assays [27,28].  Species-specific SCAR markers have been used in several studies to differentiate important Indian medicinal plants from their close relatives or adulterants [17,18]. SCAR marker for discriminating Anthricus sylvestris, an adulterant of Peucedanum praeruptorum and Peucedanum decursivum (syn. Angelica decursiva) used widely in Chinese, Japanese and Korean TM has been reported [28]. Furthermore, development of species-specific DNA markers can increase industrial application of the molecular techniques [27]. In our RAPD analysis, significant genetic polymorphism was observed among I. mauritiana and its adulterants and substitutes. The SCAR primers designed using this sequence variation was found to be specific for I. mauritiana, making the technique more stringent and specific when compared with RAPD marker. The SCAR primers can be used to authenticate the identity of I. mauritiana from other traded "Vidari" candidates like C. circinalis, A. hondala and P. tuberosa. The complete process involved in developing RAPD-based SCAR marker for authentication of I. mauritiana is summarized in Figure 4. Such efficient, precise and sensitive techniques are required in quality control of raw drugs in the herbal industry.

Funding
"Centre of Excellence" grant from Ministry of Environment and Forests, Government of India.