The Indian eri silkworm, Philosamia

The Indian eri silkworm, Philosamia ricini (Lepidoptera: Saturniidae), a commercial silk producing
insect, is reported to have originated in the Brahmaputra valley of Assam and Meghalaya15. In their
natural habitats in North-Eastern India, the silkworms are geographically isolated and have
morphological differences4
. Different natural geographic strains of P. ricini are commercially Int. J. Pure Appl. Sci. Technol., 18(1) (2013), 93-101 94
exploited in these places because of their high silk yield potential. P. ricini is a polyphagous insect
and feeds on a wide range of host plants. The primary food plant of this insect is castor (Ricinus
communis L.), but it also feeds on a wide range of food plants such as Heteropanax fragrans Seem,
Manihot utilissima Phol, Evodia flaxinifolia Hook, Ailenthus gradulosa Roxb etc. This silkworm is
multivoltine and completes five to six generations per year depending on the climatic condition of the
region6
. Strains of P. ricini show wide variation in their phenotypic traits such as fecundity, voltinism,
cocoon weight, cocoon shape, cocoon color, larval weight, larval color, silk ratio and silk quality. Due
to over exploitation of the silkworms for commercial uses coupled with deforestation, most of these
natural populations are dwindling rapidly and its preservation has become an important goal. In order
to preserve the natural biodiversity present among these populations, attempts are being made to
understand the genetic structure of each population. Assessment of the genetic diversity present
within a species is a prerequisite for developing a sustainable conservation program.
The advent of molecular biological techniques clearly showed the advantages of molecular markers
over morphobiochemical markers to analyze population diversity. As the molecular markers are stable
and environmentally independent, they are increasingly being preferred to phenotypic traits to detect
genetic variation not only among populations but also between individuals within a population. A
number of DNA marker systems such as simple sequence repeats (SSR) 21, random amplified
polymorphic DNA (RAPD) 5,7, inter-simple sequence repeats (ISSR) 17, 19and amplified fragment
length polymorphism (AFLP)18 have been used to study the population genetics of different
organisms including insects. The ISSR marker system was used to assess genetic diversity and
differentiation among different commercially exploited populations of Samia cynthia ricini from
North-Eastern states of India 2,12
.
The metazoan mitochondrial genome is a circular, double stranded DNA molecule, which is known to
have small molecular weight, rapid nucleotide mutation and rare recombination, and can be easily
handled in a laboratory compared to nuclear DNA. Because of their structural and evolutional
characteristics, mitochondrial DNA (mtDNA) sequences have been widely used as molecular markers
in the study of molecular evolution in the past several decades 1,10,11,14. The sequences of 16S
ribosomal RNA (16S rRNA) and cytochrome oxidase subunit I (CoxI) genes has been widely used for
phylogenetic studies and sequence differences in these genes reflect strain variation 13, 20
.
The present study was focused on detecting DNA sequence variation among the five commercially
exploited strains of P. ricini in the fragments of 16S ribosomal RNA (16S rRNA) and cytochrome
oxidase subunit I (CoxI) genes.