Conservation Need of Tropical Tasar Silk Insect, Antheraea Mylitta Drury (Lepidoptera: Saturniidae)-Strategies and Impact
R. Manohar Reddy
The commercially important tropical tasar silk insect, Antheraea mylitta Drury (Lepidoptera: Saturniidae) is having 44 ecoraces distributed along central India (12-31°N latitude and 72-96°E longitude) with varied phenotypic, physiological and behavioral characters. The sericigenous insect feeds primarily on Shorea robusta (Sal), Terminalia arjuna (Arjun), Terminalia tomentosa (Asan) besides variety of secondary and tertiary food plants available in tropical deciduous forests of West Bengal, Jharkhand, Bihar, Orissa, Chhattisgarh, Madhya Pradesh, Uttar Pradesh Maharashtra and Andhra Pradesh states of India. Some wild tasar ecoraces like, Raily (Chhattisgarh), Modal and Jata (Orissa), Sarihan and Laria (Jharkhand), Bhandara (Maharashtra) and Andhra (Andhra Pradesh), besides domesticated Daba and Sukinda are contributing for livelihood and alleviating the socio-economic status of around hundred and fifty thousand Indian tribal families. However, the extensive collection of nature grown cocoons, rapid deforestation and human encroachment to insect habitats has declined ecorace population. So, there is an imperative need to involve and educate local tribals on cocoon collection and insect conservation to save from extinction. The orderly involvement of forest, tribal welfare, sericulture departments and Non Government Organizations (NGOs) along with local aboriginals can up-keep the silk insect conservation for sustainable utility. This coordinated management of tasar insect population will also help in rejuvenation of their semi-domesticated relative seri-biodiversity and integrated bio-resource (flora and fauna) management of insect ecozones.
Agro forestry and economic wild insect conservation are inter-disciplinary,
multi-sector approaches of land use and its prime objective is to protect environment
to maintain the natural integrity (Gill and Lal, 2002).
The ecological education, water resource, energy, forest and wildlife managements
are needed for an environmentally sustainable rural development in India (Raffi
and Ramanujam, 2001). India has unique distinction of producing all varieties
of silk i.e., mulberry, eri, tasar and muga, with special reference to tropical
tasar silk, due to immense diversity in climatic conditions coupled with wide-ranging
ecological habitats (Jolly et al., 1974; Reddy,
2009). Silk is a proteinaceous fibre derived from cocoon (pupal nest) spun
by the caterpillars belongs to genus Bombyx feed on Morus alba
and other wild silkworms, Philosamia ricini (eri), Antheraea assama
(muga) and Antheraea mylitta (tasar), belongs to Saturniidae (Rao
et al., 2004; Suryanarayana and Srivastava, 2005).
The tropical tasar silkworm, Antheraea mylitta feeds primarily on sal
(Shorea robusta), asan (Terminalia tomentosa) and arjun (Terminalia
arjuna) and few other food plants of secondary importance are Zizyphus
mauritiana, Terminalia paniculata, Anogeissus latifolia,
Syzigium cumini, Careya arborea, Lagerstroemia parviflora and
Hardwickia binata (Mahapatra, 2009). The polyphagous
nature of the tasar silkworm is a boon to its rural tribal rearers as their
livelihood linked with the collection and sale of nature grown tasar wild cocoons
(Nayak et al., 2000; Hansda
et al., 2008; Ojha et al., 2009).
The creation of employment, alleviation of poverty and elevation of socio-economic
status of tribals are the unique features of tropical tasarculture (Suryanarayana
and Srivastava, 2005; Manohar et al., 2009a,
b). Hence, the conservation of naturally grown tropical tasar food plants
along with silk insect will contributes for the bio-diversity maintenance besides
their sustainable utilization by forest dwelling aboriginals.
The tasarculture is a cottage, agro-forestry and forestry based industry that
provides sustainable livelihood to several rural communities and country to
earn foreign exchange. The global production of raw silk is approximately 70,000
tones per year (Sohn, 2003) and the production of 16245,
1530, 428 and 117 MTs of mulberry, eri, tasar and muga raw silk respectively
during 2007- 08 by India indicates the impact of silk industry on the countys
economy (Reddy, 2009). The tasar silk industry generates
cocoons through commercial rearings along with the collection from natural habitats
by many Indian tribal families as tradition since immemorial. Though, the tropical
tasar silkworm has 44 ecoraces, very few are domesticated and the larger commercial
potential is yet to explore (Hansda et al., 2008;
Ojha et al., 2009). Further, the varied voltinism,
higher interference of environmental fluctuations on crop success and returns
made the industry unreliable compared to other agro enterprise (Thangavelu, 2002; Nayak et al., 2000). The tasarculture provides
livelihood and employment for 1.5 lakh tribals from Jharkhand, Chhattisgarh,
Orissa, Madhya Pradesh, Uttar Pradesh, West Bengal, Bihar, Maharashtra and Andhra
Pradesh states. The practice involves chain of activities like collection of
cocoons from nature or rearing of silkworm on nature grown host plants or on
economic plantations to rise cocoons, which are utilized by reelers and weavers
to produce yarn and fabrics. The silk industry has lot of socio-cultural and
traditional linkages in India and plays a vital role on rural economy and hence,
the aboriginals are practicing tasarculture simultaneously with agriculture
(Thangavelu, 2002; Reddy, 2009). Although, Indias
stands second largest silk producer in the World after China, it accounts for
only 5% of silk market and the production potential of tasar silk can be enhanced,
which is unique of the country and grow very little in rest of the wild.
The ancient man lived in a hunter gather society which depends on biodiversity
sustenance, but the advancement in agriculture, industries and urbanization
has decreased emphasis on biodiversity. The understanding biodiversity and its
preservation are the most important global challenges that biologists are facing
today. The guiding principle must always be that no living species however insignificant
or useless it may appear to be, should be allowed to go extinct. The destruction
of natural habitats, over exploitation, induction of alien species, control
of related pests and predators, pollution besides, deforestation are the main
reasons for the diminution of tasar insect wild life. On realization, that the
erosion of biodiversity may threaten the very existence of life, has awakened
man to take steps to safeguard it. The promotion of Indian tropical tasar (vanya)
silk as green occupied a unique market status and a source of cash income for
many rural tribal communities. Also, the wild tasar ecoraces are very important
for evolution and breeding of new silkworm strains with desired economic characters.
Hence, preserving tasar food plant and insect is inevitable for sustainable
utilization, besides exploiting market avenues to progress rural India (Thangavelu, 2002).
The wild tasar-biodiversity of India is facing unparallel threat of extinction
from their natural habitat due to environmental degradation and other related
issues. The alarming decline in ecorace natural multiplication is attributed
due to rampant collection, rapid deforestation and industrialization of their
natural habitats (Sinha and Sinha, 1994; Nayak
et al., 2000; Hansda et al., 2008).
Further, the conservation focus and timely attention has not been given to smaller
species like wild insects of high commercial importance (Wilson,
1987) which led to rapid dwindling of natural population even in their core
habitats. The studies based on quantitative traits needs analysis to understand
the genetic basis of their phenotypic variability (Rao and
Shamitha, 2000; Rao et al., 2004) to generate
substantial information on the genetic diversity of these populations so as
to develop appropriate strategy for its conservation in their natural habitat.
However, the said approach requires the conserved tasar seri-biodiversity initially,
as the insect conservation; investigative studies and sustainable utilization
are interlinked. In order to preserve the natural biodiversity present among
these populations, the systematic attempts are required to conserve the wild
seri biodiversity for ecological balance and for sustainable economic viability
(Hansda et al., 2008; Reddy
et al., 2009; Ojha et al., 2009).
The widespread realization that biodiversity is strongly modified by changes
in global environment has generated strategies to conserve it around the world.
The assessment of the genetic diversity present within a species (Barrett
et al., 2001; Manohar et al., 2009c)
and the wider base of natural populations of tasar flora and insect (Srivastava
et al., 1996) and tribal farmers who are interested in tasarculture
are the prerequisites of conservation programme. The tasar wild insect needs
conservation both under short and long term measures and on and off their habitat
for the sustainable utility and socio-economic up-liftment of rural tribals
(Srivastava et al., 2009). The economic values,
employment potential and global demand in general and bio-diversity conservation
in particular (Mahapatra, 2009) have motivated the conservation
of tasar insect wildlife which found rapidly depleting and getting endangered
with the following methods.
Core Zone Fortification
The interior forest patch (core-zone) in the tasar insect native habitat
has to be selected and allowed the insect to reproduce suo moto and fortify
its population. The restriction must be that nobody be allowed collecting any
of tasar insects life form (egg, larva, cocoon and adult moth) from the demarcated
core-zone, except for research purposes. This zone serves as a gene pool for
defined tasar wild ecorace which is allowed to multiply amidst utter silence
and serenity. The insect population of this zone, on proliferation, however,
will move to adjacent buffer and peripheral zones on its own helping local tribal
farmers for its sustainable utilization.
Host Plant Demarcation
A patch of tasar insect host trees in the forest has to be selected, pollard
at 5-6 height, clear from pests and predators and optimum aseptic conditions
to be maintained in and around areas. The garlands of cocoons relate to native
tasar wild insect to be hanged on to the trees adopting free spacing in between
the garlands. The host tree areas to be covered with net of the desired size
based on selected and maintained canopy. The temporary shade of paddy straw
or wild grass has to be fixed around the trees to avoid pupal mortality. The
moths emerged from the cocoons will mate; lay eggs on the host plants and helps
insect population to multiply rapidly under offered protection from diseases,
pests and predators.
Cocoon Preservation in Pagoda Device
The cocoons collected from wild to be preserved in hanging position inside
the umbrella shaped pagoda device erected under host trees. The device made
of indigenous wooden poles, paddy straw and the sides to be covered with net
to provide protection to the cocoons from pests and predators. The cocoons preserved
in the device will have better environment and protection for better coupling
and egg yielding. The gravid female moths and eggs are to be safely transferred
to their habitats for better proliferation of insect. The cocoons so preserved
in pagoda device can also be hanged on host trees of forests, just prior to
Moth, Egg and Larva Release
The male and female moths emerged from the preserved cocoons to be released
in the selected core forest area. The male and female moths on mating inside
net, the gravid female moths are to be released every day in the evening on
to the host plants of the forest. As also the eggs produced at base camp of
peripheral zone, using cocoons of the same population and same area are to be
placed in separate leaf cups of the host plant and tied vertically so that rain
water does not enter in to the leaf cups allowing the hatched larvae crawl on
to the plants. Alternatively, the young age (chawki) worms are to be reared
in chawki garden up to 2nd or 3rd day and subsequently released in natural habitat
for better multiplication of the insect.
Follow up and Exploration of Fresh Zones
After the release of cocoons, moths, eggs and larvae, the interference of
insect core zone to be cordoned off and a time bound ban on collection of cocoons
in the peripheral area also to be imposed to improve insect population and subsequent
sustainable utilization. The management activities at times also contribute
to habitat loss, which needs to be corrected in time to enhance the protection
process (Wilhere, 2002). The conservation status to
be assessed at regular intervals using suitable sampling methods, to provide
follow up in containing diseases, pests and predators and to check the conservation
impact. The survey to explore fresh zones should be conducted with time schedule
to benefit the involved tribal farmers, whose livelihood is linked with income
from the collection and sale of nature grown tasar cocoons.
Conservation of Insect along with Related Flora
Basically, the conservation plan should encompass whole spectrum of biota
and activities ranging from eco systems at macro level (in situ conservation)
and at micro leve ex situ conservation). The conservation (breeding)
of endangered wild tasar silk insect species in India is a must activity. The
intervention is needed from sericulture and forest departments along with native
tribal rearers from the habitats of tasar silk insect for ex situ conservation,
as those areas are under their vicinity and control. The conduction of regular
census on flora and fauna in collaboration with scientific institutions and
non government organizations helps assessing the field conditions and silk insect
species which need conservation. The in situ management study helps
to address the cause of decline/extinction of wild insect population in its
natural habitat, apart recommending inputs for improvement. The extensive cocoon
collections, disease out-breaks, predators attack, besides the species suitability
are to be enlightened to the native rearers for their effective participation
in insect conservation.
Conservation through Eco-Park Creation
In traditional practice, the tasar larvae feed on irregularly distributed
food plants leading to management problems and loss due to pests, diseases and
natural hazards. The newly developed economic plantation method with close spacing
can enhance foliage quality even under rain-fed and sub-marginal soils (Sinha and Sinha, 1994: Thangavelu, 2002; Rao et al., 2004).
Till now the research has been stopped on exploration of species diversity as
an individual population, but never talks about what its role in the total ecosystems.
This agri-silvicultural and tasarculture potential can create sustainable returns,
employment and rise in the living standards of forest-dwelling peoples, besides
conserving the endangered tasar silk insect. The critically endangered species
can be conserved through ex situ strategy by establishing eco-parks,
a simulated ecological niche as like their native habitat. To bring in a holistic
development of eco-parks and to achieve the main objective, we need to infuse
more technical and scientific standards in operation of eco-parks and change
the general perception of said parks from being mere picnic spots to more of
a scientific institution.
Involving VSSs, TVSs, VFCs, JFCs and NGOs
The ecological education and wildlife management is needed for an environmentally
sustainable rural development. The forest based host plants are providing livelihood
for a vulnerable section of society, besides wildlife conservation. Here, the
role of Vana Samrakshana Smithies (VSSs), Tasar Vikas Smithies (TVSs), Village
Forest Committees (VFCs) and Joint Forest Management committees (JFMs) will
play a vital role in conserving the forest flora and fauna (Balaji,
2001; Sethi and Singh, 2001; Berkes,
2004) and earn income as many of such society members being beneficiaries.
The studies on peoples participation in aforestation and conservation
programmes indicate higher involvement of landless people over marginal and
small farmers (Pande et al., 2002). The Non Government
Organizations (NGOs) have understood the potential of tasarculture in tribal
up-liftment and educating the importance of tasar insect wildlife along with
food plants for their livelihood. They work on various elements of the tasar
value chain to reduce uncertainty in returns, increase productivity, help poor
people retain more of the added value and finally to motivate the members of
societies for their active participation in conservation of tasar food plants
and silk insect. The NGOs could locate the lacunae responsible for uncertainty
in tasarculture and educated tasar rearers to set right their mistakes to make
tasarculture a successful agro forestry venture.
The tasarculture is an important co-discipline of applied forest biology that
needs special attention to promote conservation and sustainable utilization
of natural resources, as they contribute to rural tribal socio-economic and
cultural heritage. The forest conservation needs basic information on ecology,
environmental factors, climatology, flora, fauna and their inter-relationship
in the proposed site, while the life cycle, reproductive biology, voltinism
and population dynamics of tasar insect of the ecozone reveal their critical
requirements. The commercial attributes of the insect, viability in the offered
eco-climatic condition suggests their biotic and economic potential. Insects
have highly organized sensory and neuro-motor systems more comparable to those
of vertebrates and the interactions between insects and plants in case of herbivorous
insects, or hosts for parasitic insects are often called co-evolutionary (Carlsson
and Berkes, 2005). They respond to altered conditions by genetic change
and this heterogeneity or elasticity within insect species allows persistence
to efficiently face the environmental change (Edward et
al., 2002; Kakati and Chutia, 2009). Thus, exploration
of host plant-tasar insect interactions is critical to attain optimal wild silk
insect conservation, their sustainable utilization and commercial exploitation.
The single-species conservation is argued to preserve many other species by
default which is known as umbrella effect (Novotny et
al., 2002) and the conservation of silk insect wildlife indirectly conserves
forest bio-diversity. The conservation management of any ecosystem should be
an integrated endeavor concerning lower and higher flora along with invertebrate
and vertebrate fauna. Hence, the co-ordination among agencies implementing conservation,
irrespective of plant or animal, big or small in size, commercially important
or not, together with beneficiaries can have better impact and success. Hence,
the tasar silk iasect being viable forest wealth and source of income to forest
based tribals, need focus for conservation so as to exploit the available huge
tropical tasar food plant resource.
The India stands out as a treasure trove of natural tasar silk insect wealth, despite countless obstacles to their conservation and habitat restore. The tasarculture has been considered as an agro based industry of rural poor with potential of additional employment. The tasar activities are attended by local aboriginals and many of them are the members of VSS, TVS, VFC, JFC societies functioning for forest conservation. The problems though, manifold with conservation of tasar insect, the co-ordinate efforts from forest and sericulture departments with participation of forest based societies of native tasar aboriginals will facilitate conserving unique vanya seri-biodiversity as most viable resource. The conservation of tasar silk insect wildlife by feasible strategies, not only sustains its population and income of tasar rearers, but also augments the other endangered flora and fauna in the wild by default.
The author is thankful to the Director, Central Tasar Research and Training Institute, Ranchi for providing facilities while making this review article.
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