Evaluation of genetic homogeneity of in vitro-raised plants of Tecomella undulata (Sm.) Seem. using molecular markers

Abstract

Tecomella undulata (Sm.) Seem (family Bignoniaceae) is an economically and pharmaceutically important timber tree of arid regions of India. Overexploitation of natural stands coupled with minimal conservation and reforestation efforts has led to its incorporation in list of endangered species. This monotypic genus can be propagated only through seeds as no methods are available for its vegetative propagation. Therefore, protocol for multiplication of T. undulata via direct regeneration using nodal segments from mature trees has been standardized. Authentication of genetic homogeneity of these in vitro-raised plants is necessary for commercial-scale application of the developed micropropagation protocol. PCR-based molecular markers which have emerged as simple, fast, reliable, and labor-effective tools for testing the genetic homogeneity of in vitro-raised plants were used in the present study. Arbitrary (random amplified polymorphic DNA, RAPD), semi-arbitrary (inter-simple sequence repeat, ISSR; start codon targeted (SCoT) polymorphism), and sequence-based (simple sequence repeat, SSR) markers were used. DNA samples of shoots maintained in vitro for 2 years collected after every 4 subculture cycles (of 3 weeks each) and field-transferred plantlets were compared with the mother tree DNA using 131 primers (25 each of RAPD, ISSR, SCoT and 56 SSR). Scorable unambiguous and reproducible DNA fragments were produced by 77 (21 RAPD, 20 ISSR, 22 SCoT and 14 SSR) primers. A total of 71, 93, 94, and 42 distinct and scorable DNA fragments were produced by RAPD, ISSR, SCoT, and SSR primers respectively with an average of 3.38, 4.65, 4.27, and 3.0 DNA fragments per primer. The true-to-type nature of the in vitro-raised plants of T. undulata undergoing up to 32 subculture passages over a period of approximately 2 years was authenticated by monomorphic DNA fragments amplified with all primer combinations. Therefore, the developed micropropagation protocol can be safely used on a commercial scale for multiplying T. undulata plants.