Wild silk

Wild silks have been known and used in many countries from early times, although the scale of production is far smaller than that from cultivated silkworms.


Commercially reared silkworms of the species Bombyx mori (Linnaeus, 1758) are normally killed before the pupae emerge, either by pricking them with a needle or dipping the cocoons into boiling water, thus allowing the whole cocoon to be unravelled as one continuous thread. This allows a much finer cloth to be woven from the silk.

There are more than 500 species of wild silkworms in the world, although only a few are used to produce cloth. They usually produce a tougher and rougher silk than that from domesticated Bombyx mori silkworms. Wild silks are usually harvested after the moths have left the cocoons, cutting the threads in the process, so that there is not one long thread, as with domesticated silkworms.

Wild silks are more difficult to bleach and dye than silk from Bombyx mori, but most have naturally attractive colours, particularly the rich golden sheen of the silk produced by the muga silkworm from Assam, often known as Assam silk.

The cocoon shells of wild silk moths are toughened or stabilized either by tanning (cross-linking) or by mineral reinforcements (e.g. calcium oxalate).[1] Recently, a new method has been developed, demineralizing, which can remove the mineral reinforcements present in wild silks and enables wet reeling like the commercial silkworm Bombyx mori.[2][3]

Wild silk industry in India

Wild silks are often referred to in India as 'Vanya' silks:

The term 'Vanya' is of Sanskrit origin, meaning untamed, wild, or forest-based. Muga, Tasar, and Eri silkworms are not fully tamed and the world lovingly calls the silks they produce as 'wild silks'.[4]

India produces four kinds of silk: mulberry, tasar, muga and eri. The silkworm Bombyx mori is fed on mulberry leaves cultivated in plantations. Silkworms are also found wild on forest trees, e.g Antheraea paphia which produces the tasar silk (Tussah). Antheraea paphia feeds on several trees such as Anogeissus latifolia, Terminalia tomentosa, T. arjuna (Terminalia arjuna), Lagerstroemia parviflora and Madhuca indica. Wild silkworm Antheraea assamensis produces muga silk, and another wild silkworm Philosamia synthia ricini (= Samia cynthia) produces eri silk. The estimated annual production of tasar silk is 130 tonnes. Production of other types of silk exceeds 10 000 tonnes (Gupta 1994).[5]

In 2015, Adarsh Gupta K of Nagaraju's research team at Centre for DNA Fingerprinting and Diagnostics, Hyderabad, India discovered the complete sequence and the protein structure of Muga Silk Fibroin and published it in Nature (journal) Scientific Reports [6]

The eri silk worm from India feeds on the leaves of the castor plant. It is the only completely domesticated silkworm other than Bombyx mori. The silk is extremely durable, but cannot be easily reeled off the cocoon and is thus spun like cotton or wool.[7]

Wild silk industry in China

Some of the best quality wild silk is produced by silkworms in Henan. This is the only type of wild silk that can be easily dyed.[8]


Wild silk threads have been found and identified from two Indus River sites, Harappa and Chanhu-daro, dating to c. 2450–2000 BCE. This is roughly the same period as the earliest evidence of silk use in China, which is generally thought to have had the oldest silk industry in the world. The specimens of threads from Harappa appear on Scanning electron microscope analysis to be from two different species of silk moth, Antheraea mylitta and A. assamensis, while the silk from Chanhu-daro may be from a Philosamia species, (Eri silk), and this silk appears to have been reeled.[9]

Wild silks were in use in China from early times. Moreover, the Chinese were aware of their use in the Roman Empire and apparently imported goods made from them by the time of the Later Han Dynasty in the 1st to 3rd centuries CE.[10][11]

There are significant indications in the literature that wild silks were in use in Persia and in Greece by the late 5th century BCE, apparently referred to as "Amorgina" or "Amorgian garments" in Greece.[12]

Pliny the Elder, in the 1st century CE, obviously had some knowledge of how wild silkworms' cocoons were produced and utilised on the island of Kos for Coa vestis, even though his account included some fanciful ideas.[13]

List of some wild silk moths and their silk


  1. Sindya N. Bhanoo (20 May 2011). "Silk Production Takes a Walk on the Wild Side". New York Times. Retrieved 26 May 2011.
  2. Gheysens, T; Collins, A; Raina, S; Vollrath, F; Knight, D (2011). "Demineralization enables reeling of Wild Silkmoth cocoons". Biomacromolecules. American Chemical Society. 12 (6): 2257–66. doi:10.1021/bm2003362. PMID 21491856. Retrieved 26 May 2011.
  3. Wild silk deminiralizing
  4. "The Wonders Of India’s 'Vanya'Silks…"
  5. "Animal and animal products". Food and Agriculture Organization of the United Nations (FAO). Archived from the original on 2014-04-18.
  6. Adarsh Gupta. K. "Molecular architecture of silk fibroin of Indian golden silkmoth, Antheraea assama".
  7. "The Queen of Textiles." Nina Hyde. National Geographic Magazine. Vol. 165, No. 1, January, 1984, pp. 2-49.
  8. Maitra, K.K. (2007). Encyclopaedic dictionary of clothing and textiles. New Delhi: Mittal Publications. p. 211. ISBN 9788183242059.
  9. "New Evidence for Early Silk in the Indus Civilization." I. L. Good, J. M. Kenoyer and R. H. Meadow. To be published in Archaeometry. Published online 21 January 2009.
  10. Hill (2009), pp. 25, 477–480.
  11. Hill (2004). Appendix E.
  12. "Silk in Greece." Gisela M. A. Richter. American Journal of Archaeology, Vol. 33, No. 1. (January–March 1929), pp. 27–33.
  13. Pliny XI, 75-78 (77 CE). From: Natural History – A Selection. Pliny the Elder, pp. 157–158. Translated by John F. Healy. London. Penguin Books. (1991).
  14. 1 2 3 4 5 6 7 "Chapter 9". FAO.org. Archived from the original on 2012-10-21.
  15. 1 2 "Raw & Organic Silk: Facts behind the Fibers"
  16. "Saturniidae". Archived from the original on 2009-04-13.
  17. "Orange-tipped oakworm moth Anisota senatoria (J.E. Smith, 1797)". Butterflies and Moths of North America.
  18. "Anisota senatoria". Archived from the original on 2012-02-24.
  19. "Automeris io moth (Fabricius, 1775)". Archived from the original on 2013-01-17.
  20. "Kalahari Wild Silk" By Amy Schoeman
  21. Bombyx in Merriam Webster.


  • Arunkumar, K.P.; Metta, Muralidhar & Nagaraju, J. (2006): Molecular phylogeny of silkmoths reveals the origin of domesticated silkmoth, Bombyx mori from Chinese Bombyx mandarina and paternal inheritance of Antheraea proylei mitochondrial DNA. Molecular Phylogenetics and Evolution 40(2): 419–427. doi:10.1016/j.ympev.2006.02.023 (HTML abstract). Supplementary figure 1 (JPG) Supplementary figure 2 (JPG) Supplementary figure 3 (JPG)
  • Hill, John E. 2004. The Peoples of the West. A draft annotated translation of the 3rd century Weilüe – see Appendix E.
  • Hill, John E. (2009) Through the Jade Gate to Rome: A Study of the Silk Routes during the Later Han Dynasty, 1st to 2nd Centuries CE. John E. Hill. BookSurge, Charleston, South Carolina. ISBN 978-1-4392-2134-1. See p. 25 and "Appendix C - Wild Silks", pp. 477–480.
  • "Studies on the filament of tasar silkworm, Antheraea mylitta D (Andhra local ecorace)." G. Shamitha and A. Purushotham Rao. CURRENT SCIENCE, VOL. 90, NO. 12, 25 JUNE 2006, pp. 1667–1671. PDF file downloadable from:
  • Tuskes, PM, JP Tuttle and MM Collins. 1996. The wild silk moths of North America. Cornell University Press. ISBN 0-8014-3130-1
  • Yoshitake, N. (1968): Phylogenetic aspects on the origin of Japanese race of the silkworm, Bombyx mori L.. Journal of Sericological Sciences of Japan 37: 83–87.
  • Yukuhiro, K.; Sezutsu, H.; Itoh, M.; Shimizu, K. & Banno, Y. (2002): Significant Levels of Sequence Divergence and Gene Rearrangements have Occurred Between the Mitochondrial Genomes of the Wild Mulberry Silkmoth, Bombyx mandarina, and its Close Relative, the Domesticated Silkmoth, Bombyx mori. Molecular Biology and Evolution 19(8): 1385–1389. PDF fulltext
  • Gheysens, T.;Collins, A.;Raina, S.;Vollrath, F.;Knight, D. (2011): Demineralization enables reeling of Wild Silkmoth cocoons. Biomacromolecules.
  • ScienceDaily (2011): New Method of Unreeling Cocoons Could Extend Silk Industry Beyond Asia. Sciencedaily. here
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